Prosthetic heart valve devices, prosthetic mitral valves and associated systems and methods

ABSTRACT

Devices and methods for implantation at a native mitral valve having a non-circular annulus and leaflets. One embodiment of the device includes a valve support having a first region configured to be attached to a prosthetic valve with a plurality of prosthetic leaflets and a second region. The device can further include an anchoring member having a longitudinal dimension and including a first portion configured to contact tissue at the non-circular annulus, a second portion configured to be attached to the valve support, and a lateral portion between the first portion and the second portion. The second portion of the anchoring member is attached to the second region of the valve support while in a low-profile configuration in which the anchoring member and the valve support are configured to pass through vasculature of a human. The lateral portion is transverse to the longitudinal dimension. The anchoring member and the valve support are configured to move from the low-profile configuration to an expanded configuration in which the first portion of the anchoring member at least partially adapts to the non-circular annulus of the native mitral valve and the first region of the valve support is spaced inwardly from the first portion of the anchoring member relative to the longitudinal dimension of the anchoring member such that a shape of the first region of the valve support is at least partially independent of a shape of the first portion of the anchoring member.

CROSS-REFERENCES TO RELATED APPLICATIONS

The present application is a continuation of U.S. patent applicationSer. No. 14/720,369, filed on May 22, 2015, now allowed, entitled“PROSTHETIC HEART VALVE DEVICES, PROSTHETIC MITRAL VALVES AND ASSOCIATEDSYSTEMS AND METHODS”, which is a continuation-in-part of InternationalApplication No. PCT/US2012/61219, filed on Oct. 19, 2012, entitled“PROSTHETIC HEART VALVE DEVICES, PROSTHETIC MITRAL VALVES AND ASSOCIATEDSYSTEMS AND METHODS”, which claims priority to U.S. Provisional PatentApplication No. 61/605,699, filed Mar. 1, 2012, entitled “SYSTEM FORMITRAL VALVE REPLACEMENT,” to U.S. Provisional Patent Application No.61/549,044, filed Oct. 19, 2011, entitled “CONFORMABLE SYSTEM FOR MITRALVALVE REPLACEMENT,” both of which are incorporated herein in theirentireties by reference. The present application incorporates thesubject matter of (1) International PCT Patent Application No.PCT/US2012/043636, entitled “PROSTHETIC HEART VALVE DEVICES ANDASSOCIATED SYSTEMS AND METHODS,” filed Jun. 21, 2012; (2) U.S.Provisional Patent Application No. 61/549,037, entitled “SYSTEM FORMITRAL VALVE REPLACEMENT,” filed Oct. 19, 2011; and (3) InternationalPCT Patent Application No. PCT/US2012/61215, (Attorney Docket NO.82829-8005WO00), entitled “DEVICES, SYSTEMS AND METHODS FOR HEART VALVEREPLACEMENT,” filed Oct. 19, 2012, in their entireties by reference.

TECHNICAL FIELD

The present technology relates generally to prosthetic heart valvedevices. In particular, several embodiments are directed to prostheticmitral valves and devices for percutaneous repair and/or replacement ofnative mitral valves and associated systems and methods.

BACKGROUND

Conditions affecting the proper functioning of the mitral valve include,for example, mitral valve regurgitation, mitral valve prolapse andmitral valve stenosis. Mitral valve regurgitation is a disorder of theheart in which the leaflets of the mitral valve fail to coapt intoapposition at peak contraction pressures, resulting in abnormal leakingof blood from the left ventricle into the left atrium. There are anumber of structural factors that may affect the proper closure of themitral valve leaflets. For example, many patients suffering from heartdisease experience dilation of the heart muscle, resulting in anenlarged mitral annulus. Enlargement of the mitral annulus makes itdifficult for the leaflets to coapt during systole. A stretch or tear inthe chordae tendineae, the tendons connecting the papillary muscles tothe inferior side of the mitral valve leaflets, may also affect properclosure of the mitral annulus. A ruptured chordae tendineae, forexample, may cause a valve leaflet to prolapse into the left atrium dueto inadequate tension on the leaflet. Abnormal backflow can also occurwhen the functioning of the papillary muscles is compromised, forexample, due to ischemia. As the left ventricle contracts duringsystole, the affected papillary muscles do not contract sufficiently toeffect proper closure.

Mitral valve prolapse, or when the mitral leaflets bulge abnormally upin to the left atrium, causes irregular behavior of the mitral valve andmay also lead to mitral valve regurgitation. Normal functioning of themitral valve may also be affected by mitral valve stenosis, or anarrowing of the mitral valve orifice, which causes impedance of fillingof the left ventricle in diastole.

Typically, treatment for mitral valve regurgitation has involved theapplication of diuretics and/or vasodilators to reduce the amount ofblood flowing back into the left atrium. Other procedures have involvedsurgical approaches (open and intravascular) for either the repair orreplacement of the valve. For example, typical repair approaches haveinvolved cinching or resecting portions of the dilated annulus.

Cinching of the annulus has been accomplished by the implantation ofannular or peri-annular rings which are generally secured to the annulusor surrounding tissue. Other repair procedures have also involvedsuturing or clipping of the valve leaflets into partial apposition withone another.

Alternatively, more invasive procedures have involved the replacement ofthe entire valve itself where mechanical valves or biological tissue areimplanted into the heart in place of the mitral valve. These invasiveprocedures are conventionally done through large open thoracotomies andare thus very painful, have significant morbidity, and require longrecovery periods.

However, with many repair and replacement procedures, the durability ofthe devices or improper sizing of annuloplasty rings or replacementvalves may result in additional problems for the patient. Moreover, manyof the repair procedures are highly dependent upon the skill of thecardiac surgeon where poorly or inaccurately placed sutures may affectthe success of procedures.

Less invasive approaches to aortic valve replacement have been developedin recent years. Examples of pre-assembled, percutaneous prostheticvalves include, e.g., the CoreValve Revalving® System fromMedtronic/Corevalve Inc. (Irvine, Calif., USA) and the Edwards-Sapien®Valve from Edwards Lifesciences (Irvine, Calif., USA). Both valvesystems include an expandable frame housing a tri-leaflet bioprostheticvalve. The frame is expanded to fit the substantially symmetric,circular and rigid aortic annulus. This gives the expandable frame inthe delivery configuration a symmetric, circular shape at the aorticvalve annulus, suitable to supporting a tri-leaflet prosthetic valve(which requires such symmetry for proper coaptation of the prostheticleaflets). Thus, aortic valve anatomy lends itself to an expandableframe housing a replacement valve since the aortic valve anatomy issubstantially uniform, symmetric, and fairly rigid.

Mitral valve replacement, compared with aortic valve replacement, posesunique anatomical obstacles, rendering percutaneous mitral valvereplacement significantly more challenging than aortic valvereplacement. First, unlike the relatively symmetric and uniform aorticvalve, the mitral valve annulus has a non-circular D-shape orkidney-like shape, with a non-planar, saddle-like geometry often lackingsymmetry. Such unpredictability makes it difficult to design a mitralvalve prosthesis having the ability to conform to the mitral annulus.Lack of a snug fit between the prosthesis and the native leaflets and/orannulus may leave gaps therein, creating backflow of blood through thesegaps. Placement of a cylindrical valve prosthesis, for example, mayleave gaps in commissural regions of the native valve, potentiallyresulting in perivalvular leaks in those regions.

Current prosthetic valves developed for percutaneous aortic valvereplacement are unsuitable for adaptation to the mitral valve. First,many of these devices require a direct, structural connection betweenthe device structure which contacts the annulus and/or leaflets and thedevice structure which supports the prosthetic valve. In severaldevices, the same stent posts which support the prosthetic valve alsocontact the annulus or other surrounding tissue, directly transferringto the device many of the distorting forces exerted by the tissue andblood as the heart contracts during each cardiac cycle. Most cardiacreplacement devices further utilize a tri-leaflet valve, which requiresa substantially symmetric, cylindrical support around the prostheticvalve for proper opening and closing of the three leaflets over years oflife. If these devices are subject to movement and forces from theannulus and other surrounding tissues, the prostheses may be compressedand/or distorted causing the prosthetic leaflets to malfunction.Moreover, the typical diseased mitral annulus is much larger than anyavailable prosthetic valve. As the size of the valve increases, theforces on the valve leaflets increase dramatically, so simply increasingthe size of an aortic prosthesis to the size of a dilated mitral valveannulus would require dramatically thicker, taller leaflets, and mightnot be feasible.

In addition to its irregular, unpredictable shape, which changes sizeover the course of each heartbeat, the mitral valve annulus lacks asignificant amount of radial support from surrounding tissue. The aorticvalve, for example, is completely surrounded by fibro-elastic tissue,helping to anchor a prosthetic valve by providing native structuralsupport. The mitral valve, on the other hand, is bound by musculartissue on the outer wall only. The inner wall of the mitral valve isbound by a thin vessel wall separating the mitral valve annulus from theinferior portion of the aortic outflow tract. As a result, significantradial forces on the mitral annulus, such as those imparted by anexpanding stent prostheses, could lead to collapse of the inferiorportion of the aortic tract with potentially fatal consequences.

The chordae tendineae of the left ventricle may also present an obstaclein deploying a mitral valve prosthesis. This is unique to the mitralvalve since aortic valve anatomy does not include chordae. The maze ofchordae in the left ventricle makes navigating and positioning adeployment catheter that much more difficult in mitral valve replacementand repair. Deployment and positioning of a prosthetic valve oranchoring device on the ventricular side of the native mitral valve isfurther complicated by the presence of the chordae.

The triscuspid valve on the right side of the heart, although itnormally has three leaflets, poses similar challenges to less invasivetreatment as the mitral valve. Therefore there is a need for a betterprosthesis to treat tricuspid valve disease as well.

Given the difficulties associated with current procedures, there remainsthe need for simple, effective, and less invasive devices and methodsfor treating dysfunctional heart valves.

BRIEF DESCRIPTION OF THE DRAWINGS

Many aspects of the present disclosure can be better understood withreference to the following drawings. The components in the drawings arenot necessarily to scale. Instead, emphasis is placed on illustratingclearly the principles of the present disclosure. Furthermore,components can be shown as transparent in certain views for clarity ofillustration only and not to indicate that the illustrated component isnecessarily transparent.

FIGS. 1 and 2 are schematic illustrations of a mammalian heart havingnative valve structures suitable for replacement with various prostheticheart valve devices in accordance with embodiments of the presenttechnology.

FIG. 3 is a schematic cross-sectional side view of a native mitral valveshowing the annulus and leaflets.

FIG. 4A is a schematic illustration of the left ventricle of a hearthaving either i) prolapsed leaflets in the mitral valve, or ii) mitralvalve regurgitation in the left ventricle of a heart having impairedpapillary muscles, and which are suitable for combination with variousprosthetic heart valve devices in accordance with embodiments of thepresent technology.

FIG. 4B is a schematic illustration of a heart in a patient sufferingfrom cardiomyopathy, and which is suitable for combination with variousprosthetic heart valve devices in accordance with embodiments of thepresent technology.

FIG. 5A is a schematic illustration of a native mitral valve of a heartshowing normal closure of native mitral valve leaflets.

FIG. 5B is a schematic illustration of a native mitral valve of a heartshowing abnormal closure of native mitral valve leaflets in a dilatedheart, and which is suitable for combination with various prostheticheart valve devices in accordance with embodiments of the presenttechnology.

FIG. 5C is a schematic illustration of a mitral valve of a heart showingdimensions of the annulus, and which is suitable for combination withvarious prosthetic heart valve devices in accordance with embodiments ofthe present technology.

FIG. 6A is a schematic, cross-sectional illustration of the heartshowing an antegrade approach to the native mitral valve from the venousvasculature, in accordance with various embodiments of the presenttechnology.

FIG. 6B is a schematic, cross-sectional illustration of the heartshowing access through the inter-atrial septum (IAS) maintained by theplacement of a guide catheter over a guidewire, in accordance withvarious embodiments of the present technology.

FIGS. 7 and 8 are schematic, cross-sectional illustrations of the heartshowing retrograde approaches to the native mitral valve through theaortic valve and arterial vasculature, in accordance with variousembodiments of the present technology.

FIG. 9 is a schematic, cross-sectional illustration of the heart showingan approach to the native mitral valve using a trans-apical puncture inaccordance with various embodiments of the present technology.

FIG. 10A shows an isometric view of a prosthetic heart valve device inaccordance with an embodiment of the present technology.

FIG. 10B illustrates a cut-away view of a heart showing the prosthetictreatment device of FIG. 10A implanted at a native mitral valve inaccordance with an embodiment of the present technology.

FIGS. 10C-10F are side, perspective cut-away, top, and bottom views,respectively, of a prosthetic heart valve device in accordance with anembodiment of the present technology.

FIG. 11A is a side view of a valve support in an expanded configurationin accordance with an embodiment of the present technology.

FIGS. 11B-11D are isometric views of additional embodiments of valvesupports with prosthetic valves mounted therein in accordance with thepresent technology.

FIG. 11E shows an isometric view of a prosthetic heart valve device inaccordance with another embodiment of the present technology.

FIGS. 12A-12C are side views of various longitudinal ribs flexing inresponse to a distorting force in accordance with further embodiments ofthe present technology.

FIG. 13A is a schematic, cross-sectional view of a prosthetic heartvalve device in accordance with another embodiment of the presenttechnology.

FIGS. 13B-13F are partial side views of prosthetic heart valve devicesillustrating a variety of longitudinal rib configurations in accordancewith additional embodiments of the present technology.

FIG. 14A is a schematic top view of a native mitral valve illustratingthe major and minor axes.

FIGS. 14B-14C are schematic top views of an anchoring member in anexpanded configuration and in a deployed configuration, respectively, inaccordance with an embodiment of the present technology.

FIG. 15 is an isometric view of a prosthetic heart valve deviceillustrated in a deployed configuration in accordance with an additionalembodiment of the present technology.

FIG. 16A is a top view of a prosthetic heart valve device illustrated inan expanded configuration in accordance with a further embodiment of thepresent technology.

FIGS. 16B-16C are a first side view and a second side view,respectively, of the prosthetic heart valve device of FIG. 16A.

FIG. 16D is a side view of a prosthetic heart valve device showing thelongitudinal axis of the anchoring member off-set from the longitudinalaxis of the valve support by a tilt angle in accordance with anotherembodiment of the present technology.

FIG. 16E is a schematic top view of a native mitral valve in the heartviewed from the left atrium and showing the prosthetic treatment deviceof FIG. 16A-16C implanted at the native mitral valve in accordance withan embodiment of the present technology.

FIGS. 17A-17C are schematic top and first and second side views of theprosthetic heart valve device of FIG. 16A showing dimensions and taperangles of various aspects of the device in accordance with embodimentsof the present technology.

FIG. 18 is an isometric view of an anchoring member illustrated in anexpanded configuration in accordance with yet another embodiment of thepresent technology.

FIGS. 19A-19C are isometric, side and top views, respectively, of aprosthetic heart valve device having a sealing member in accordance witha further embodiment of the present technology.

FIG. 20A is an isometric view of a prosthetic heart valve device withouta sealing member in accordance with an embodiment of the presenttechnology.

FIGS. 20B-20E are isometric views of prosthetic heart valve deviceshaving sealing members in accordance with additional embodiments of thepresent technology.

FIGS. 21A-21B are cross-sectional side and isometric views of aprosthetic heart valve device having a tubular valve support member inaccordance with a further embodiment of the present technology.

FIGS. 21C-21F are partial cross-sectional side views and an isometricview of prosthetic heart valve devices having a tubular valve supportmember in accordance with other embodiments of the present technology.

FIGS. 22A-22G and 22I-22K are enlarged side views of various mechanismsof coupling a valve support to an anchoring member in accordance withadditional embodiments of the present technology.

FIG. 22H is a side view of a post in the prosthetic heart valve deviceof FIG. 40G.

FIGS. 23A-23B are enlarged side views of additional mechanisms forcoupling an anchoring member to a valve support member in accordancewith further embodiments of the present technology.

FIG. 24A is a perspective view of an integral connection between a valvesupport and an anchoring member in accordance with an additionalembodiment of the present technology.

FIGS. 24B-24D are enlarged views of additional embodiments of anintegral connection between a valve support and an anchoring member inaccordance with the present technology.

FIG. 25A is a partial cross-sectional view of a prosthetic heart valvedevice having an anchoring member and a valve support in accordance withan embodiment of the present technology.

FIG. 25B is an enlarged view of the designated box shown in FIG. 25A

FIGS. 26A-26D are schematic cross-sectional views of prosthetic heartvalve devices having atrial retainers and implanted at a native mitralvalve in accordance with various embodiments of the present technology.

FIG. 27 is a side view of an anchoring member having a vertical portionat the upstream end for engaging the annulus in accordance with anotherembodiment of the present technology.

FIG. 28 is a side view of a prosthetic heart valve device in an expandedconfiguration and having a plurality of stabilizing elements inaccordance with an embodiment of the present technology.

FIG. 29 is an enlarged schematic, side view of a prosthetic heart valvedevice having an extended arm in accordance with an embodiment of thepresent technology.

FIGS. 30A-30C are enlarged partial side views of a prosthetic heartvalve device having arms coupled to the device at various angles withrespect to a longitudinal axis of the device in accordance with furtherembodiments of the present technology.

FIGS. 31A-31C are enlarged, partial side views of a prosthetic heartvalve device having arms of various lengths coupled to the device inaccordance with additional embodiments of the present technology.

FIGS. 32A, 32B, 32C, and 32D are cross-sectional views of a heart withan implanted prosthetic heart valve device having arms disposed on aninward-facing surface of the leaflets in accordance with variousembodiments of the present technology.

FIGS. 32A-1, 32B-1, 32C-1 and 32D-1 are enlarged views of the armsengaging the inward-facing surface of the leaflets as shown in FIGS.32A. 32B. 32C and 32D, respectively in accordance with variousembodiments of the present technology.

FIGS. 33A-33C are schematic views illustrating various embodiments oftissue engaging elements for use with prosthetic heart valve devices inaccordance with the present technology.

FIGS. 34A, 34B and 34C are cross-sectional views of a heart with animplanted prosthetic heart valve device having arms with tissue engagingelements disposed on an inward-facing surface of the leaflets inaccordance with various embodiments of the present technology.

FIGS. 34A-1, 34B-1 and 34C-1 are enlarged views of the arms engaging theinward-facing surface of the leaflets as shown in FIGS. 34A, 34B and34C, respectively in accordance with various embodiments of the presenttechnology.

FIGS. 35A-35C are side views of prosthetic heart valve devices and shownimplanted at a mitral valve (illustrated in cross-section), the deviceshaving arms for engaging an outward-facing surface of the nativeleaflets in accordance with further embodiments of the presenttechnology.

FIG. 35C-1 is an enlarged view of the arm engaging the inward-facingsurface of the leaflets as shown in FIG. 35C in accordance with variousembodiments of the present technology.

FIG. 36A is a side view of a prosthetic heart valve device and shownimplanted at a mitral valve (illustrated in cross-section), the devicehaving arms for engaging an outward-facing surface of the nativeleaflets and arms for engaging an inward-facing surface of the nativeleaflets in accordance with an additional embodiment of the presenttechnology.

FIG. 36B is an enlarged view of the arms engaging the inward-facing andoutward-facing surfaces of the leaflets as shown in FIG. 36A.

FIGS. 37A-37D are enlarged side views of additional embodiments of armssuitable for use with a prosthetic heart valve device in accordance withthe present technology.

FIG. 38A is a side view of a prosthetic heart valve device having aplurality of non-interconnected arms in accordance with a furtherembodiment of the present technology.

FIG. 38B is a side view of a prosthetic heart valve device having aplurality of circumferentially connected arms in accordance with afurther embodiment of the present technology.

FIGS. 39A-39D are schematic top views of arm location patterns inaccordance with additional embodiments of the present technology.

FIGS. 40A-40D are side views of prosthetic heart valve devices havingtissue engaging elements on varying structures of the device inaccordance with additional embodiments of the present technology.

FIGS. 40E-40G are enlarged side views of tissue engaging elementssuitable for use with prosthetic heart valve devices in accordance withother embodiments of the present technology.

FIGS. 40A-40T are enlarged side views of embodiments of tissue engagingelements suitable for use with prosthetic heart valve devices inaccordance with additional embodiments of the present technology.

FIG. 41 is an isometric view of a prosthetic heart valve device having aplurality of annulus engaging elements in accordance with a furtherembodiment of the present technology.

FIGS. 42A-42B are cross-sectional side and enlarged views of aprosthetic heart valve device having tissue engaging elements deployablefrom a plurality of tubular ribs in accordance with another embodimentof the present technology.

FIGS. 43A-43B are an isometric view and an enlarged detail view of aprosthetic heart valve device having a sealing member configured withtissue engaging elements in accordance with another embodiment of thepresent technology

FIGS. 44A-44F are enlarged side views of embodiments of tissue engagingelements suitable for use with prosthetic heart valve devices inaccordance with additional embodiments of the present technology.

FIG. 45A is an isometric view of a prosthetic heart valve device havinga plurality of tethers between the anchoring member 110 and the valvesupport 120 in accordance with an embodiment of the present technology.

FIG. 45B is an isometric view of a prosthetic heart valve device havinga plurality of septa between the anchoring member 110 and the valvesupport 120 in accordance with another embodiment of the presenttechnology.

FIG. 46A is side partial cut-away view of a delivery system inaccordance with an embodiment of the present technology.

FIG. 46B is an enlarged cross-sectional view of a distal end of adelivery system in accordance with an embodiment of the presenttechnology.

FIGS. 46C-46D are enlarged partial side views of a valve supportconfigured for use with the delivery system of FIG. 46B in accordancewith an embodiment of the present technology.

FIGS. 47A-47D are cross-sectional views of a heart showing an antegradeor trans-septal approach to the mitral valve in accordance with anembodiment of the present technology.

FIGS. 48A-48C are cross-sectional views of the heart illustrating amethod of implanting a prosthetic heart valve device using atrans-septal approach in accordance with another embodiment of thepresent technology.

FIGS. 49A-49B are cross-sectional views of the heart showing aretrograde approach to the mitral valve via the aorta and left ventriclein accordance with a further embodiment of the present technology.

FIGS. 50A-50B are cross-sectional views of the heart illustrating afurther embodiment of a method of implanting the prosthetic heart valvedevice using a trans-apical approach in accordance with aspects of thepresent technology.

FIGS. 51A-51B are partial side views of a delivery system wherein aprosthetic heart valve device is mounted on an expandable balloon of adelivery catheter in accordance with another embodiment of the presenttechnology.

FIGS. 52A-52D are cross-sectional views of a heart showing a method ofdelivering a prosthetic heart valve device having a valve supportmovably coupled to an anchoring member in accordance with a furtherembodiment of the present technology.

FIGS. 53A-53D are partial side views showing various mechanisms formovably coupling the valve support to the anchoring member in accordancewith additional embodiments of the present technology.

FIG. 53E is a partial top view of the device of FIG. 53D.

FIG. 53F is a side view of an alternative mechanism for slideablycoupling a valve support and anchoring member in accordance with anotherembodiment of the present technology.

FIGS. 53G-53H are schematic side views of a prosthetic heart valvedevice showing yet another mechanism for coupling the valve support tothe anchoring member in accordance with a further embodiment of thepresent technology.

FIG. 54A is a cross-sectional side view of another embodiment of adelivery system for the prosthetic heart valve device in accordance withother aspects of the present technology.

FIG. 54B is a partial cross-sectional side view of a distal portion ofthe delivery system of FIG. 54A.

FIGS. 55A-55C are perspective views of the delivery system of FIG. 46illustrating the steps of delivering the prosthetic treatment device ofthe invention.

FIG. 56 is a side cross-sectional view of a further embodiment of adelivery system for the prosthetic treatment device of the invention.

FIGS. 57A-57D are isometric views of prosthetic treatment devices inaccordance with additional embodiments of the present technology.

FIG. 57E is a schematic cross-sectional view of the prosthetic heartvalve device of FIG. 57A implanted at a native mitral valve inaccordance with an embodiment of the present technology.

FIGS. 58A-58D are cross-sectional views of a heart showing a method ofdelivering a prosthetic heart valve device to a native mitral valve inthe heart using a trans-apical approach in accordance with anotherembodiment of the present technology.

FIGS. 59A-59C are isometric views of prosthetic treatment devices inaccordance with additional embodiments of the present technology.

FIG. 59D is a schematic cross-sectional view of a prosthetic heart valvedevice implanted at a native mitral valve in accordance with anotherembodiment of the present technology.

FIGS. 60A-60B are cross-sectional side views of a distal end of adelivery catheter for delivering the prosthetic heart valve device ofFIG. 59C to a native mitral valve in the heart in accordance withanother embodiment of the present technology.

FIG. 61 is a side view of a prosthetic heart valve device having firstand second anchoring members for engaging supra-annular and subannulartissue of the mitral valve, respectively, in accordance with yet anotherembodiment of the present technology.

FIGS. 62A-62C are partial cross-sectional side views of a distal end ofa delivery system showing delivery of the prosthetic heart valve deviceof FIG. 61 at a mitral valve in accordance with another embodiment ofthe present technology.

FIG. 63 is an isometric side view of a prosthetic heart valve devicehaving an anchoring member with a supra-annular engaging rim and asubannular engaging ring in accordance with a further embodiment of thepresent technology.

FIGS. 64A-64D are side views of the prosthetic heart valve device ofFIG. 63 showing embodiments of methods for deploying the device at themitral valve annulus in accordance with aspects of the presenttechnology.

FIG. 65A is a cross-sectional view of a prosthetic heart valve devicehaving an inflatable anchoring member and shown implanted in a nativemitral valve of a heart in accordance with another embodiment of thepresent disclosure.

FIG. 65B is a partial cross-sectional side view of a distal end of adelivery system suitable for delivery of the prosthetic heart valvedevice of FIG. 65A in accordance with another embodiment of the presenttechnology.

FIGS. 66A-66D are cross-sectional views of prosthetic heart valvedevices having tillable chambers in accordance with additionalembodiments of the present technology.

FIGS. 67A-67B are isometric views of additional embodiments ofprosthetic heart valve devices in accordance with aspects of the presenttechnology.

FIGS. 68A-68B are side views of prosthetic heart valve devices having apositioning element in accordance with an additional embodiments of thepresent technology.

FIGS. 69A-69E are cross-sectional and side views of prosthetic heartvalve devices shown in an expanded configuration and configured inaccordance with an additional embodiment of the present technology.

FIG. 70 is a cross-sectional side view of another prosthetic heart valvedevice configured in accordance with an embodiment of the presenttechnology.

FIG. 71 is a cross-sectional side view of yet another prosthetic heartvalve device configured in accordance with an embodiment of the presenttechnology.

FIG. 72 is an isometric view of a prosthetic heart valve device inaccordance with another embodiment of the technology.

FIG. 73 is a side view of the prosthetic heart valve device of FIG. 72.

FIG. 74 is a bottom view of the prosthetic heart valve device of FIG.72.

FIG. 75 is a side view of a prosthetic heart valve device in accordancewith another embodiment of the technology.

FIG. 76 is a bottom view of the prosthetic heart valve device of FIG.75.

FIG. 77 is a side view of a prosthetic heart valve device in accordancewith another embodiment of the technology.

FIG. 78 is an isometric view of a prosthetic heart valve device inaccordance with another embodiment of the technology.

FIGS. 79A and 79B are partial anatomical cross-sections of a heart (H)and side views of an embodiment of a prosthetic heart valve device beingimplanted in accordance with a method of the present technology.

FIG. 79C is a partial anatomical cross-section of a heart (H) showingthe placement of the prosthetic heart valve device in accordance with anembodiment of the technology.

FIG. 79D is a partial anatomical cross-section of a heart (H) showingthe placement of the prosthetic heart valve device in accordance with anembodiment of the technology

FIGS. 80A-80K are schematic cross-sectional views of several embodimentsof prosthetic heart valve devices in accordance with the presenttechnology.

FIG. 81A is a cross-sectional view of a prosthetic heart valve device inaccordance with another embodiment of the present technology.

FIG. 81B is a top view of the prosthetic heart valve device of FIG. 81A.

FIG. 82A is an isometric view of a prosthetic heart valve device inaccordance with another embodiment of the present technology.

FIG. 82B is a cross-sectional view of the prosthetic heart valve deviceof FIG. 82A taken along line 20B-20B.

FIG. 83 is a schematic cross-sectional view of a prosthetic heart valvedevice in accordance with another embodiment of the present technology.

FIGS. 84A-84C are schematic cross-section views of the operation ofprosthetic heart valve devices in accordance with the presenttechnology.

FIGS. 85A-85C are schematic side views of a portion of prosthetic heartvalve devices in accordance with the present technology.

DETAILED DESCRIPTION

Specific details of several embodiments of the technology are describedbelow with reference to FIGS. 1-85C. Although many of the embodimentsare described below with respect to devices, systems, and methods forpercutaneous replacement of a native mitral valve using prosthetic valvedevices, other applications and other embodiments in addition to thosedescribed herein are within the scope of the technology. Additionally,several other embodiments of the technology can have differentconfigurations, components, or procedures than those described herein. Aperson of ordinary skill in the at, therefore, will accordinglyunderstand that the technology can have other embodiments withadditional elements, or the technology can have other embodimentswithout several of the features shown and described below with referenceto FIGS. 1-85C.

With regard to the terms “distal” and “proximal” within thisdescription, unless otherwise specified, the terms can reference arelative position of the portions of a prosthetic valve device and/or anassociated delivery device with reference to an operator and/or alocation in the vasculature or heart. For example, a referring to adelivery catheter suitable to deliver and position various prostheticvalve devices described herein, “proximal” can refer to a positioncloser to the operator of the device or an incision into thevasculature, and “distal” can refer to a position that is more distantfrom the operator of the device or further from the incision along thevasculature (e.g., the end of the catheter). With respect to aprosthetic heart valve device, the terms “proximal” and “distal” canrefer to the location of portions of the device with respect to thedirection of blood flow. For example, proximal can refer to an upstreamposition or a position of blood inflow, and distal can refer to adownstream position or a position of blood outflow. For ease ofreference, throughout this disclosure identical reference numbers and/orletters are used to identify similar or analogous components orfeatures, but the use of the same reference number does not imply thatthe parts should be construed to be identical. Indeed, in many examplesdescribed herein, the identically numbered parts are distinct instructure and/or function. The headings provided herein are forconvenience only.

Overview

Systems, devices and methods are provided herein for percutaneousreplacement of native heart valves, such as mitral valves. Several ofthe details set forth below are provided to describe the followingexamples and methods in a manner sufficient to enable a person skilledin the relevant art to practice, make and use them. Several of thedetails and advantages described below, however, may not be necessary topractice certain examples and methods of the technology. Additionally,the technology may include other examples and methods that are withinthe scope of the claims but are not described in detail.

Embodiments of the present technology provide systems, methods andapparatus to treat valves of the body, such as heart valves includingthe mitral valve. The apparatus and methods enable a percutaneousapproach using a catheter delivered intravascularly through a vein orartery into the heart. Additionally, the apparatus and methods enableother less-invasive approaches including trans-apical, trans-atrial, anddirect aortic delivery of a prosthetic replacement valve to a targetlocation in the heart. The apparatus and methods enable a prostheticdevice to be anchored at a native valve location by engagement with asubannular surface of the valve annulus and/or valve leaflets.Additionally, the embodiments of the devices and methods as describedherein can be combined with many known surgeries and procedures, such asknown methods of accessing the valves of the heart (e.g., the mitralvalve or triscuspid valve) with antegrade or retrograde approaches, andcombinations thereof.

The devices and methods described herein provide a valve replacementdevice that has the flexibility to adapt and conform to thevariably-shaped native mitral valve anatomy while mechanically isolatingthe prosthetic valve from the anchoring portion of the device. Severalembodiments of the device effectively absorb the distorting forcesapplied by the native anatomy. The device has the structural strengthand integrity necessary to withstand the dynamic conditions of the heartover time, thus permanently anchoring a replacement valve and making itpossible for the patient to resume a substantially normal life. Thedevices and methods further deliver such a device in a less-invasivemanner, providing a patient with a new, permanent replacement valve butalso with a lower-risk procedure and a faster recovery.

In accordance with various embodiments of the present technology, adevice for repair or replacement of a native valve of a heart isdisclosed. The native valve has an annulus and leaflets, and the deviceincludes an anchoring member having a first portion configured to engagetissue on or under the annulus and to deform in a non-circular shape toconform to the tissue. The anchoring member also can include a secondportion. The device also includes a valve support coupled to the secondportion of the anchoring member and configured to support a prostheticvalve and having a cross-sectional shape. In various embodiments, thefirst portion of the anchoring member is mechanically isolated from thevalve support such that the cross-sectional shape of the valve supportremains sufficiently stable so that the prosthetic valve remainscompetent when the anchoring member is deformed in the non-circularshape.

Some embodiments of the disclosure are directed to prosthetic heartvalve devices for implantation at a native mitral valve wherein themitral valve has an annulus and leaflets. In one embodiment, the devicecan have an anchoring member positionable in a location between theleaflets, wherein a first portion of the anchoring member is expendableto a dimension larger than a corresponding dimension of the annulus. Inthis embodiment, upstream movement of the anchoring member is blocked byengagement of the upstream portion with tissue on or near the annulus.The anchoring member can also include a second portion. The device canalso include a valve support coupled to the second portion of theanchoring member, wherein an upstream region of the valve support isspaced radially inward from at least the first portion of the anchoringmember. The valve support can be configured to support a prostheticvalve.

In another arrangement, a device for implantation at a native valvehaving an annulus and leaflets can include a hyperboloidic anchoringmember having an upstream end configured to engage an inward facingsurface of the leaflets downstream of the annulus and a downstream end,wherein the upstream end has a larger cross-sectional area than thedownstream end. The device can also include a valve support positionedin the anchoring member and configured to support a prosthetic valve.The valve support is coupled to the anchoring member at a locationspaced substantially downstream from the upstream end and is uncoupledto the anchoring member at the upstream end.

Other aspects of the disclosure are directed to prosthetic heart valvedevices for repair or replacement of a native heart valve of a patient,wherein the heart valve has an annulus and leaflets. In one embodiment,the device includes an anchoring member having a first portion having afirst cross-sectional dimension and second portion having a secondcross-sectional dimension less than the first cross-sectional dimension.The first portion is configured to engage cardiac tissue to retain theanchoring member in a fixed longitudinal position relative to theannulus. The device can also include a valve support coupled to thesecond portion of the anchoring member and configured to support aprosthetic valve. The valve support can be radially separated from thefirst portion of the anchoring member such that the first portion candeform inwardly without substantially deforming the valve support.

In a further arrangement, the present disclosure also is directed to adevice for implantation at a native heart valve. The device can includean anchoring member having an upstream end configured to engage tissueon or downstream of a native annulus of the heart valve, and a valvesupport configured to support a prosthetic valve. The valve support canbe coupled to the anchoring member. In some arrangements, the anchoringmember can resist upstream migration of the device without an element ofthe device extending behind native valve leaflets.

In another embodiment, the device can include an anchoring memberpositionable between the leaflets of the native valve. The anchoringmember can have a plurality of tissue engaging elements on an upstreamend and/or on an exterior surface which are configured to engage cardiactissue on or near the annulus so as to prevent migration of the devicein the upstream direction. The device can also include a valve supportpositioned within an interior of the anchoring member and coupled to adownstream portion of the anchoring member, wherein the valve support isradially separated from at least an upstream portion of the anchoringmember.

Further embodiments of the disclosure are directed to a device forrepair or replacement of a native mitral valve having an annulus and apair of leaflets that include a support structure having an upperregion, a lower region, and an interior to retain a prosthetic valve.The device can also include an anchoring member surrounding at least aportion of the support structure, wherein the anchoring member ispositionable between the leaflets and has a plurality of flexibleelements (e.g., wires, laser cut metal elements, etc.) arranged in adiamond pattern, an upper portion, and a lower portion. The upperportion of the anchoring member can be flared outwardly in a proximaldirection such that proximal ends of the flexible elements pointradially outward so as to engage cardiac tissue on or near the annulusand inhibit migration of the device in the upstream direction. The lowerregion of the support structure can be coupled to the lower portion ofthe anchoring member, and the lower region of the support structure canbe mechanically isolated from at least deformation of the flared upperportion of the anchoring member.

Other embodiments of the disclosure are directed to prosthetic heartvalve devices having a cylindrical support and an anchor defined by astructure separate from the cylindrical support. The cylindrical supportcan have a longitudinal axis and an interior along the longitudinal axisthrough which blood may flow. The anchor can have a non-circularcross-section with an outwardly flared upstream end configured to engagesubannular tissue of a mitral valve. The anchor can also surround thecylindrical support and be coupled to the support at a downstream endopposite the upstream end.

In a further embodiment, the device can include an expandable valvesupport configured for placement between the two leaflets. The supportcan have a first region, a second region and an interior in which avalve may be coupled. The device can also include an anchoring memberhaving a first portion and a second portion, the second portion coupledto the second region of the valve support. The first portion of theanchoring member can extend outwardly away from the second portion. Theanchoring member can have a first perimeter at the first portionconfigured to engage tissue on or near the annulus. The anchoring membercan be mechanically isolated from the valve support such that a forceexerted radially at or near the first perimeter will not substantiallyalter a shape of the valve support.

Additional embodiments are directed to devices to treat a heart valve ofa patient that include an inner frame and an outer frame coupled to theinner frame. The inner frame can have an outer surface and an innersurface that is configured to support a prosthetic valve. The outerframe can have an upper portion with a cross-sectional dimension greaterthan a corresponding cross-sectional dimension of an annulus of themitral valve, wherein the upper portion is configured to engage tissueat or below the annulus of the mitral valve. The upper portion can alsoprevent migration of the device in an upward or upstream directionduring ventricular systole. Further, the upper portion of the outerframe can be mechanically isolated from the inner frame.

In a further embodiment, the device can include a cylindrical innerskeleton and an outer skeleton coupled to the inner skeleton andpositionable between the leaflets downstream of the annulus. The outerskeleton can be deformable to a non-circular cross-section while theinner skeleton remains substantially circular in cross-section. Theinner skeleton can have an interior to which a prosthetic valve may becoupled. The outer skeleton can have a plurality of flexible elements(e.g., wires, laser cut metal elements, etc.), wherein at least aportion of the flexible elements can be configured to engage nativesubannular tissue so as to prevent migration of the device in anupstream direction. In one embodiment, the plurality of flexible wiresare arranged in a diamond configuration.

In yet a further embodiment, a prosthetic mitral valve device caninclude a valve support having upstream and downstream ends, an interiorin which a valve may be coupled, and a perimeter. The device can alsoinclude an anchoring member having a flared upstream portion and adownstream portion coupled to the perimeter of the valve support. Theupstream portion can be mechanically isolated from the valve support andcan be configured to engage subannular tissue of a native mitral valve.Additionally, the device can be moveable into a plurality ofconfigurations including a first configuration in which the valvesupport and the anchoring member are radially contracted, and whereinthe valve support has a first cross-sectional shape. The device can alsomove into a second configuration in which the valve support and theanchoring member are radially expended and in which the valve supporthas a second cross-sectional shape. Additionally, the device can moveinto a third configuration in which the anchoring member is engaged withand deformed by the subannular tissue while the valve support remains inthe second cross-sectional shape.

In some embodiments, the device may comprise an atrial retainerextending from the anchoring member or the valve support to a positionat least partially upstream of the native mitral annulus. The atrialextension member may comprise an atrial engagement structure adapted toengage an upstream surface (e.g., supra-annular surface) of the annulusand/or an interior wall of the atrium for further stabilizing oranchoring the device. For example, the atrial retainer can blockdownstream movement of the device.

Some embodiments of the device may further comprise one or morestabilizing members to inhibit the device from tilting or beingdisplaced laterally. The stabilizing members may comprise a plurality ofarms extending radially outwardly from the valve support and/or theanchoring member. The arms may be configured to extend behind the nativeleaflets and/or into engagement with the ventricular wall or papillarymuscles.

A further embodiment, in accordance with another aspect of the presentdisclosure, is directed to a device for implantation at a native mitralvalve, wherein the native mitral valve has an annulus and leaflets. Thedevice can include a valve support having upstream and downstream ends,an interior in which a valve may be coupled, and an outer surface, andinclude a first anchoring member having a first flared upstream portionand a first downstream portion coupled to the outer surface of the valvesupport. In other embodiments, the first downstream portion can becoupled to inner surface of the valve support, or in some embodiments,to an end of the valve support. The device can also include a secondanchoring member at least partially surrounding the first anchoringmember. The first upstream portion of the first anchoring member can bemechanically isolated from the valve support and configured to engagesupra-annular tissue of the native mitral valve. The second anchoringmember can have a second flared upstream portion and a second downstreamportion coupled to the outer surface of the valve support, wherein thesecond upstream portion can be mechanically isolated from the valvesupport and is configured to engage subannular tissue of the nativemitral valve.

In yet a further embodiment, the device for implantation can include aradially expandable anchoring member configured to engage native tissueon or downstream of the annulus. The anchoring member can have a firstlongitudinal length on a posterior leaflet-facing side and a secondlength on an anterior leaflet-facing side. In certain embodiments, thefirst length can be greater than the second length such that occlusionof a left ventricle outflow tract (LVOT) is limited. The device can alsoinclude a valve support, or alternatively a prosthetic valve, coupled toan interior or to an end of the anchoring member.

Other embodiments of the present technology provide a device forimplantation at a native mitral valve having an annulus and leaflets,wherein the device includes a valve support having upstream anddownstream ends, an interior in which a valve may be coupled, and anouter surface. The device can also include an anchoring member having aflared upstream portion and a downstream portion coupled to the outersurface of the valve support, wherein the upstream portion can have anupper ring and a lower ring coupled to the upper ring. The device canfurther include a plurality of flexible annulus engaging elementsdistributed around a circumference of the anchoring member and couplingthe upper ring to the lower ring. The lower ring is configured to movein an upstream direction toward the upper ring such that the annulus isreceived between the upper and lower rings and within the annulusengaging elements.

The disclosure further provides systems for delivery of prostheticvalves and other devices using endovascular or other minimally invasiveforms of access. For example, embodiments of the present technologyprovide a system to treat a mitral valve of a patient, in which themitral valve has an annulus. The system comprises a device to treat themitral valve as described herein and a catheter having a lumenconfigured to retain the device within the catheter.

In other aspects, a system for replacing a native valve in a patient isprovided. The system can include an elongated catheter body having adistal end and a proximal end, and a housing coupled to the distal endof the catheter body and having a closed end and an open end. The systemcan also include a plunger within the housing which is axially movablerelative to the housing, and an actuator at the proximal end of thecatheter body and coupled to the plunger such that moving the actuatormoves the housing axially relative to the plunger. The system canfurther include a prosthetic valve device having a collapsedconfiguration and an expanded configuration. The prosthetic valve devicecan be positionable in the housing in the collapsed configuration andcan be releasable proximally from the housing by moving the actuator.

In yet another aspect, embodiments of the present technology provide amethod of treating a heart valve of a patient. The mitral valve has anannulus and leaflets coupled to the annulus. The method can includeimplanting a device as described herein within or adjacent to theannulus. The device, in some embodiments, can include a valve supportcoupled to and at least partially surrounded by an anchoring member. Theanchoring member can be disposed between the leaflets and an upstreamportion of the anchoring member can be configured to engage tissue on ordownstream of the annulus to prevent migration of the device in anupstream direction. Further, the valve support can be mechanicallyisolated from the anchoring member at least at the upstream portion.

In yet a further aspect, embodiments of the present technology provide amethod for replacement of a native mitral valve having an annulus andleaflets. The method can include positioning a device as describedherein between the leaflets, while the device is in a collapsedconfiguration. The method can also include allowing the prostheticdevice to expand such that an anchoring member of the prosthetic deviceis in a subannular position in which it engages tissue on or downstreamof the annulus. The anchoring member can have a diameter larger than acorresponding diameter of the annulus in the subannular position. Themethod can further include allowing a valve support to expand within theanchoring member, wherein the valve support is coupled to the anchoringmember. In various embodiments, the valve support can be mechanicallyisolated from the anchoring member such that deformation of theanchoring member when the anchoring member engages the tissue does notsubstantially deform the valve support. In some arrangements, certainregions of the valve support may deform, but a support region suitablefor retaining a prosthetic valve does not substantially deform such thatleaflet coaptation of the prosthetic valve would not be compromised.

The devices and methods disclosed herein can be configured for treatingnon-circular, asymmetrically shaped valves and bileaflet or bicuspidvalves, such as the mitral valve. It can also be configured for treatingother valves of the heart such as the tricuspid valve. Many of thedevices and methods disclosed herein can further provide for long-term(e.g., permanent) and reliable anchoring of the prosthetic device evenin conditions where the heart or native valve may experience gradualenlargement or distortion.

Cardiac and Mitral Valve Physiology

FIGS. 1 and 2 show a normal heart H. The heart comprises a left atriumthat receives oxygenated blood from the lungs via the pulmonary veins PVand pumps this oxygenated blood through the mitral valve MV into theleft ventricle LV. The left ventricle LV of a normal heart H in systoleis illustrated in FIG. 2. The left ventricle LV is contracting and bloodflows outwardly through the aortic valve AV in the direction of thearrows. Back flow of blood or “regurgitation” through the mitral valveMV is prevented since the mitral valve is configured as a “check valve”which prevents back flow when pressure in the left ventricle is higherthan that in the left atrium LA.

The mitral valve MV comprises a pair of leaflets having free edges FEwhich meet evenly, or “coapt” to close, as illustrated in FIG. 2. Theopposite ends of the leaflets LF are attached to the surrounding heartstructure via an annular region of tissue referred to as the annulus AN.FIG. 3 is a schematic cross-sectional side view of an annulus andleaflets of a mitral valve. As illustrated, the opposite ends of theleaflets LF are attached to the surrounding heart structure via afibrous ring of dense connective tissue referred to as the annulus AN,which is distinct from both the leaflet tissue LF as well as theadjoining muscular tissue of the heart wall. The leaflets LF and annulusAN are comprised of different types of cardiac tissue having varyingstrength, toughness, fibrosity, and flexibility. Furthermore, the mitralvalve MV may also comprise a unique region of tissue interconnectingeach leaflet LF to the annulus AN, referred to herein as leaflet/annulusconnecting tissue LAC (indicated by overlapping cross-hatching). Ingeneral, annular tissue AN is tougher, more fibrous, and stronger thanleaflet tissue LF.

Referring to FIG. 2, the free edges FE of the mitral leaflets LF aresecured to the lower portions of the left ventricle LV through chordaetendineae CT (referred to hereinafter “chordae”) which include aplurality of branching tendons secured over the lower surfaces of eachof the valve leaflets LF. The chordae CT in turn, are attached to thepapillary muscles PM, which extend upwardly from the lower wall of theleft ventricle LV and interventricular septum IVS.

Referring now to FIGS. 4A to 4B, a number of structural defects in theheart can cause mitral valve regurgitation. Ruptured chordae RCT, asshown in FIG. 4A, can cause a valve leaflet LF2 to prolapse sinceinadequate tension is transmitted to the leaflet via the chordae. Whilethe other leaflet LF1 maintains a normal profile, the two valve leafletsdo not properly meet and leakage from the left ventricle LV into theleft atrium LA will occur, as shown by the arrow.

Regurgitation also occurs in the patients suffering from cardiomyopathywhere the heart is dilated and the increased size prevents the valveleaflets LF from meeting properly, as shown in FIG. 4B. The enlargementof the heart causes the mitral annulus to become enlarged, making itimpossible for the free edges FE to meet during systole. The free edgesof the anterior and posterior leaflets normally meet along a line ofcoaptation C as shown in Figure SA, but a significant gap G can be leftin patients suffering from cardiomyopathy, as shown in FIG. 5B.

Mitral valve regurgitation can also occur in patients who have sufferedischemic heart disease where the functioning of the papillary muscles PMis impaired, as illustrated in FIG. 4A. As the left ventricle LVcontracts during systole, the papillary muscles PM do not contractsufficiently to effect proper closure. One or both of the leaflets LF1and LF2 then prolapse. Leakage again occurs from the left ventricle LVto the left atrium LA.

FIGS. 5A-5C further illustrate the shape and relative sizes of theleaflets L of the mitral valve. Referring to FIG. 5C, it may be seenthat the overall valve has a generally “D”-shape or kidney-like shape,with a long axis MVA1 and a short axis MVA2. In healthy humans the longaxis MVA1 is typically within a range from about 33.3 mm to about 42.5mm in length (37.9+/−4.6 mm), and the short axis MVA2 is within a rangefrom about 26.9 to about 38.1 mm in length (32.5+/−5.6 mm). However,with patients having decreased cardiac function these values can belarger, for example MVA1 can be within a range from about 45 mm to 55 mmand MVA2 can be within a range from about 35 mm to about 40 mm. The lineof coaptation C is curved or C-shaped, thereby defining a relativelylarge anterior leaflet AL and substantially smaller posterior leaflet PL(FIG. 5A). Both leaflets appear generally crescent-shaped from thesuperior or atrial side, with the anterior leaflet AL beingsubstantially wider in the middle of the valve than the posteriorleaflet. As illustrated in FIG. 5A, at the opposing ends of the line ofcoaptation C the leaflets join together at corners called theanterolateral commissure AC and posteromedial commissure PC,respectively.

FIG. 5C shows the shape and dimensions of the annulus of the mitralvalve. The annulus is an annular area around the circumference of thevalve comprised of fibrous tissue which is thicker and tougher than thatof the leaflets LF and distinct from the muscular tissue of theventricular and atrial walls. The annulus may comprise a saddle-likeshape with a first peak portion PP1 and a second peak portion PP2located along an interpeak axis IPD, and a first valley portion VP1 anda second valley portion VP2 located along an intervalley axis IVD. Thefirst and second peak portion PP1 and PP2 are higher in elevationrelative to a plane containing the nadirs of the two valley portionsVP1, VP2, typically being about 8-19 mm higher in humans, thus givingthe valve an overall saddle-like shape. The distance between the firstand second peak portions PP1, PP2, referred to as interpeak span IPD, issubstantially shorter than the intervalley span IVD, the distancebetween first and second valley portions VP1, VP2.

A person of ordinary skill in the art will recognize that the dimensionsand physiology of the patient may vary among patients, and although somepatients may comprise differing physiology, the teachings as describedherein can be adapted for use by many patients having variousconditions, dimensions and shapes of the mitral valve. For example, workin relation to embodiments suggests that some patients may have a longdimension across the annulus and a short dimension across the annuluswithout well-defined peak and valley portions, and the methods anddevice as described herein can be configured accordingly.

Access to the Mitral Valve

Access to the mitral valve or other atrioventricular valve can beaccomplished through the patient's vasculature in a percutaneous manner.By percutaneous it is meant that a location of the vasculature remotefrom the heart is accessed through the skin, typically using a surgicalcut down procedure or a minimally invasive procedure, such as usingneedle access through, for example, the Seldinger technique. The abilityto percutaneously access the remote vasculature is well-known anddescribed in the patent and medical literature. Depending on the pointof vascular access, the approach to the mitral valve may be antegradeand may rely on entry into the left atrium by crossing the inter-atrialseptum. Alternatively, approach to the mitral valve can be retrogradewhere the left ventricle is entered through the aortic valve. Oncepercutaneous access is achieved, the interventional tools and supportingcatheter(s) may be advanced to the heart intravascularly and positionedadjacent the target cardiac valve in a variety of manners, as describedherein.

Using a trans-septal approach, access is obtained via the inferior venacava IVC or superior vena cava SVC, through the right atrium RA, acrossthe inter-atrial septum IAS and into the left atrium LA above the mitralvalve MV.

As shown in FIG. 6A, a catheter 1 having a needle 2 may be advanced fromthe inferior vena cava IVC into the right atrium RA. Once the catheter 1reaches the anterior side of the inter-atrial septum IAS, the needle 2may be advanced so that it penetrates through the septum, for example atthe fossa ovalis FO or the foramen ovale into the left atrium LA. Atthis point, a guidewire may be exchanged for the needle 2 and thecatheter 1 withdrawn.

As shown in FIG. 6B, access through the inter-atrial septum IAS mayusually be maintained by the placement of a guide catheter 4, typicallyover a guidewire 6 which has been placed as described above. The guidecatheter 4 affords subsequent access to permit introduction of thedevice to replace the mitral valve, as described in more detail herein.

In an alternative antegrade approach (not shown), surgical access may beobtained through an intercostal incision, preferably without removingribs, and a small puncture or incision may be made in the left atrialwall. A guide catheter may then be placed through this puncture orincision directly into the left atrium, sealed by a purse string-suture.

The antegrade or trans-septal approach to the mitral valve, as describedabove, can be advantageous in many respects. For example, the use of theantegrade approach will usually allow for more precise and effectivecentering and stabilization of the guide catheter and/or prostheticvalve device. Precise positioning facilitates accuracy in the placementof the prosthetic valve device. The antegrade approach may also reducethe risk of damaging the chordae tendinae or other subvalvularstructures during catheter and interventional tool introduction andmanipulation. Additionally, the antegrade approach may decrease risksassociated with crossing the aortic valve as in retrograde approaches.This can be particularly relevant to patients with prosthetic aorticvalves, which cannot be crossed at all or without substantial risk ofdamage.

An example of a retrograde approach to the mitral valve is illustratedin FIGS. 7 and 8. The mitral valve MV may be accessed by an approachfrom the aortic arch AA, across the aortic valve AV, and into the leftventricle LV below the mitral valve MV. The aortic arch AA may beaccessed through a conventional femoral artery access route, as well asthrough more direct approaches via the brachial artery, axillary artery,radial artery, or carotid artery. Such access may be achieved with theuse of a guidewire 6. Once in place, a guide catheter 4 may be trackedover the guidewire 6. Alternatively, a surgical approach may be takenthrough an incision in the chest, preferably intercostally withoutremoving ribs, and placing a guide catheter through a puncture in theaorta itself. The guide catheter 4 affords subsequent access to permitplacement of the prosthetic valve device, as described in more detailherein.

In some specific instances, a retrograde arterial approach to the mitralvalve may be selected due to certain advantages. For example, use of theretrograde approach can eliminate the need for a trans-septal puncture.The retrograde approach is also more commonly used by cardiologists andthus has the advantage of familiarity.

An additional approach to the mitral valve is via trans-apical puncture,as shown in FIG. 9. In this approach, access to the heart is gained viathoracic incision, which can be a conventional open thoracotomy orsternotomy, or a smaller intercostal or sub-xyphoid incision orpuncture. An access cannula is then placed through a puncture, sealed bya purse-string suture, in the wall of the left ventricle at or near theapex of the heart. The catheters and prosthetic devices of the inventionmay then be introduced into the left ventricle through this accesscannula.

The trans-apical approach has the feature of providing a shorter,straighter, and more direct path to the mitral or aortic valve. Further,because it does not involve intravascular access, the trans-apicalprocedure can be performed by surgeons who may not have the necessarytraining in interventional cardiology to perform the catheterizationsrequired in other percutaneous approaches.

The prosthetic treatment device may be specifically designed for theapproach or interchangeable among approaches. A person of ordinary skillin the art can identify an appropriate approach for an individualpatient and design the treatment apparatus for the identified approachin accordance with embodiments described herein.

Orientation and steering of the prosthetic valve device can be combinedwith many known catheters, tools and devices. Such orientation may beaccomplished by gross steering of the device to the desired location andthen refined steering of the device components to achieve a desiredresult.

Gross steering may be accomplished by a number of methods. A steerableguidewire may be used to introduce a guide catheter and the prosthetictreatment device into the proper position. The guide catheter may beintroduced, for example, using a surgical cut down or Seldinger accessto the femoral artery in the patient's groin. After placing a guidewire,the guide catheter may be introduced over the guidewire to the desiredposition. Alternatively, a shorter and differently shaped guide cathetercould be introduced through the other routes described above.

A guide catheter may be pre-shaped to provide a desired orientationrelative to the mitral valve. For access via the trans-septal approach,the guide catheter may have a curved, angled or other suitable shape atits tip to orient the distal end toward the mitral valve from thelocation of the septal puncture through which the guide catheterextends. For the retrograde approach, as shown in FIGS. 7 and 8, guidecatheter 4 may have a pre-shaped J-tip which is configured so that itturns toward the mitral valve MV after it is placed over the aortic archAA and through the aortic valve AV. As shown in FIG. 7, the guidecatheter 4 may be configured to extend down into the left ventricle LVand to assume a J-shaped configuration so that the orientation of aninterventional tool or catheter is more closely aligned with the axis ofthe mitral valve MV. In either case, a pre-shaped guide catheter may beconfigured to be straightened for endovascular delivery by means of astylet or stiff guidewire which is passed through a lumen of the guidecatheter. The guide catheter might also have pull-wires or other meansto adjust its shape for more fine steering adjustment.

Selected Embodiments of Prosthetic Heart Valve Devices and Methods

Embodiments of the present technology as described herein can be used totreat one or more of the valves of the heart as described herein, and inparticular embodiments, can be used for treatment of the mitral valve.Introductory examples of prosthetic heart valve devices, systemcomponents and associated methods in accordance with embodiments of thepresent technology are described in this section with reference to FIGS.10A-56. It will be appreciated that specific elements, substructures,advantages, uses, and/or other features of the embodiments describedwith reference to FIGS. 10A-56 can be suitably interchanged, substitutedor otherwise configured with one another and/or with the embodimentsdescribed with reference to FIGS. 57A-71 in accordance with additionalembodiments of the present technology. Furthermore, suitable elements ofthe embodiments described with reference to FIGS. 10A-71 can be used asstand-alone and/or self-contained devices.

Systems, devices and methods are provided herein for percutaneousimplantation of prosthetic heart valves in a heart of a patient. In someembodiments, methods and devices are presented for the treatment ofvalve disease by minimally invasive implantation of artificialreplacement heart valves. In one embodiment, the artificial replacementvalve can be a prosthetic valve device suitable for implantation andreplacement of a mitral valve between the left atrium and left ventriclein the heart of a patient. In another embodiment, the prosthetic valvedevice can be suitable for implantation and replacement of another valve(e.g., a bicuspid or tricuspid valve) in the heart of the patient. FIG.10A shows an isometric view of a prosthetic heart valve device 100 in anexpanded configuration 102 in accordance with an embodiment of thepresent technology, and FIG. 10B is a schematic illustration of across-sectional view of a heart depicting the left atrium, leftventricle, and native mitral valve of the heart. FIG. 10B also shows anembodiment of the expandable prosthetic valve device 100 implanted inthe native mitral valve region of the heart.

As shown in FIG. 10A, the device 100 can include a flexible anchoringmember 110 at least partially surrounding and coupled to an inner valvesupport 120. The device 100 can further include a prosthetic valve 130coupled to, mounted within, or otherwise carried by the valve support120. FIGS. 10C-10F are side, perspective cut-away, top, and bottomviews, respectively, of the prosthetic heart valve device 100 inaccordance with the present technology. The device 100 can also includeone or more sealing members 140 and tissue engaging elements 170. Forexample, the sealing member 140 can, in one embodiment, extend around aninner wall 141 of the anchoring member 110 and/or around an exteriorsurface 127 of the valve support 120 to prevent paravalvular (e.g.,paraprosthetic) leaks between the device 100 and the native tissueand/or between the anchoring member 110 and the valve support 120. Inanother specific embodiment, and as shown in FIG. 10A, the tissueengaging elements 170 can be spikes disposed on an upstream perimeter113 of the anchoring member 110 and extend in an upward and/or radiallyoutward direction to engage, and in some embodiments, penetrate thenative tissue to facilitate retention or maintain position of the devicein a desired implanted location. The tissue engaging elements 170 mayalso be included around an outer wall 142 of the anchoring member 110and can extend outwardly to engage and, in some embodiments, penetratethe native valve leaflets or other adjacent tissue. Additionally, thevalve support 120 can have a plurality of coupling features 180, such aseyelets, around an upstream end 121 to facilitate loading, retention anddeployment of the device 100 within and from a delivery catheter (notshown), as further described herein.

The prosthetic heart valve device 100 can be movable between a deliveryconfiguration (not shown), an expanded configuration 102 (FIG. 10A), anda deployed configuration 104 (FIG. 10B). In the delivery configuration,the prosthetic heart valve device 100 has a low profile suitable fordelivery through small-diameter guide catheters positioned in the heartvia the trans-septal, retrograde, or trans-apical approaches describedherein. In some embodiments, the delivery configuration of theprosthetic heart valve device 100 will preferably have an outer diameterno larger than about 8-10 mm for trans-septal approaches, about 8-10 mmfor retrograde approaches, or about 8-12 mm for trans-apical approachesto the mitral valve MV. As used herein, “expanded configuration” refersto the configuration of the device when allowed to freely expand to anunrestrained size without the presence of constraining or distortingforces. “Deployed configuration,” as used herein, refers to the deviceonce expanded at the native valve site and subject to the constrainingand distorting forces exerted by the native anatomy.

Referring back to FIG. 3, “subannular,” as used herein, refers to aportion of the mitral valve MV that lies on or downstream DN of theplane PO of the native orifice. As used herein, the plane PO of thenative valve orifice is a plane generally perpendicular to the directionof blood flow through the valve and which contains either or both themajor axis MVA1 or the minor axis MVA2 (FIG. 5C). Thus, a subannularsurface of the mitral valve MV is a tissue surface lying on theventricular side of the plane PO, and preferably one that facesgenerally downstream, toward the left ventricle LV. The subannularsurface may be disposed on the annulus AN itself or the ventricular wallbehind the native leaflets LF, or it may comprise a surface of thenative leaflets LF, either inward-facing IF or outward-facing OF, whichlies below the plane PO. The subannular surface or subannular tissue maythus comprise the annulus AN itself, the native leaflets LF,leaflet/annulus connective tissue, the ventricular wall or combinationsthereof.

In operation, the prosthetic heart valve device 100 can beintravascularly delivered to a desired location in the heart, such as anintracardiac location near the mitral valve MV, while in the delivery(e.g., collapsed) configuration within a delivery catheter (not shown).Referring to FIG. 10B, the device 100 can be advanced to a positionwithin or downstream of the native annulus AN where the device 100 canbe released from the delivery catheter to enlarge toward the expandedconfiguration 102 (FIG. 10A). The device 100 will engage the nativetissue at the desired location, which will deform or otherwise alter theshape of the device 100 into the deployed configuration 104 (FIG. 10B).Once released from the catheter, the device 100 can be positioned suchthat at least a portion of the flexible anchoring member 110 engages asubannular surface of the native valve so as to resist systolic forcesand prevent upstream migration of the device 100 (FIG. 10B). In theembodiment illustrated in FIG. 10B, the upstream perimeter 113 of theanchoring member 110 engages the inward-facing surfaces IF (FIG. 3) ofthe native leaflets LF, which are pushed outwardly and folded under thenative annulus AN. The leaflets LF engage a ventricular side of theannulus AN and are prevented from being pushed further in the upstreamdirection, thus maintaining the anchoring member 110 below the plane ofthe native valve annulus. The tissue engaging elements 170 can penetratethe tissue of the leaflets LF and/or the annulus AN to stabilize andfirmly anchor the device 100. In some embodiments, however, someportions of the anchoring member 110 may extend above the annulus AN,with at least some portions of the anchoring member 110 engaging tissuein a subannular location to prevent migration of the device 100 towardthe left atrium LA. As shown in FIG. 10B, the leaflets LF can lie inapposition against the outer wall 142 of the anchoring member 110forming a blood-tight seal with the sealing member 140. The tissueengaging elements 170 can apply pressure against or, in anotherembodiment, penetrate the annulus AN or leaflets LF along the outer wall142 of the anchoring member 110 to further stabilize the device 100 andprevent migration.

In accordance with aspects of the present technology, the proximal orupper end of the anchoring member 110, while in a deployed configuration104, conforms to the irregularly-shaped mitral annulus AN, effectivelysealing the device 100 against the native annulus AN to anchor thedevice and to prevent paravalvular leaks. As described further herein,the anchoring member 110 mechanically isolates the valve support 120from distorting forces present in the heart such that the anchoringmember 110 may adapt and/or conform to native forces while the valvesupport 120 maintains its structural integrity. Accordingly, theanchoring member 110 can be sufficiently flexible and resilient and/orcoupled to the valve support 120 in such a manner as to mechanicallyisolate the valve support 120 from the forces exerted upon the anchoringmember 110 by the native anatomy. Alternatively, or in addition to theabove features, the valve support 120 may be more rigid and/or havegreater radial strength than the radial strength of the anchoring member110 so as to maintain its cylindrical or other desired shape and toensure proper opening and closing of the prosthetic valve 130 housedwithin the valve support structure 120. In some embodiments, the valvesupport 120 has a radial strength of at least 100%, or in otherembodiments at least 200%, and in further embodiments at least 300%,greater than a radial strength of the anchoring member 110. In oneembodiment, the valve support 120 can have a radial strength ofapproximately 10 N to about 12 N. Thus, if deformed from its unbiasedshape by exerting a radially compressive force against itscircumference, the valve support 120 can exhibit a hoop force which isabout 2 to about 20 times greater for a given degree of deformation thanwill be exhibited by the anchoring member 110.

As illustrated in FIGS. 10A-10F, the anchoring member 110 has adownstream portion Ill and an upstream portion 112 opposite thedownstream portion 111 relative to a longitudinal axis 101 of the device100. The upstream portion 112 of the anchoring member 110 can be agenerally outward oriented portion of the device 100, as shown in FIG.10D. In one embodiment the anchoring member 110 has a generallyhyperboloidic shape, such as the shape of a two-sheet hyperboloid. Inanother example, the downstream portion 111 can be substantiallycircular in cross-section while the upstream portion 112 can begenerally non-circular. In some embodiments, the anchoring member 110can include a series of circumferentially positioned, resilientlydeformable and flexible longitudinal ribs 114 which, in someembodiments, are connected circumferentially by deformable and/orflexible connectors 116. Once deployed, at least a portion of theupstream ends of the longitudinal ribs 114 engage a subannular surfaceof the native valve (e.g., mitral valve). As described in more detailbelow, certain embodiments of longitudinal ribs 114 are configured topenetrate subannular tissue to anchor and further stabilize the device100.

Additionally, FIGS. 10A-10F also illustrate that the longitudinal ribs114 and/or circumferential connectors 116 may be arranged in a varietyof geometrical patterns. In the examples shown in FIGS. 10A-10F, theconnectors 116 are formed in a chevron configuration. One of ordinaryskill will recognize that diamond-shaped patterns, sinusoidalconfigurations, closed cells, open cells, or other circumferentiallyexpandable configurations are also possible. In some embodiments, thelongitudinal ribs 114 may be divided along their length into multiple,separated segments (not shown), e.g. where the connectors 116interconnect with the longitudinal ribs 114. The plurality of connectors116 and ribs 114 can be formed from a deformable material or from aresilient or shape memory material (e.g., Nitinol). In otherembodiments, the anchoring member 110 can comprise a mesh or wovenconstruction in addition to or in place of the longitudinal ribs 114and/or circumferential connectors 116. For example, the anchoring member110 could include a tube or braided mesh formed from a plurality offlexible wires or filaments arranged in a diamond pattern or otherconfiguration. In another example, a metal tube can be laser cut toprovide a desired rib or strut geometry. The diamond configuration can,in some embodiments, provide column strength sufficient to inhibitmovement of the device 100 relative the annulus under the force ofsystolic blood pressure against the valve 130 mounted in the valvesupport 120. In a particular example, the anchoring member 120 can beformed of a preshaped Nitinol tube having, for example, a wall thicknessof approximately 0.010 inches to about 0.030 inches.

FIGS. 11A-11E show several embodiments of valve supports 120 that can beused in embodiments of the prosthetic heart valve device 100 shown inFIGS. 10A-10F. FIGS. 11A-11D are side and isometric views of the valvesupport 120 shown in an expanded configuration 102, and FIG. 11E is anisometric view of another embodiment of a prosthetic heart valve device100 disposed in an expanded configuration 102 in accordance with thepresent technology. Referring to FIGS. 10A-10F and 11A-11E together,several embodiments of the valve support 120 can be generallycylindrical having an upstream end 121 and a downstream end 123 formedaround a longitudinal axis 101 with a circular, oval, elliptical,kidney-shaped, D-shaped, or other suitable cross-sectional shapeconfigured to support a tricuspid or other prosthetic valve 130. In someembodiments, the valve support 120 includes a plurality of posts 122connected circumferentially by a plurality of struts 124. The posts 122and struts 124 can be arranged in a variety of geometrical patterns thatcan expand and provide sufficient resilience and column strength formaintaining the integrity of the prosthetic valve 130. For example, theplurality of posts 122 can extend longitudinally across multiple rows ofstruts 124 to provide column strength to the valve support 120. However,in other embodiments, the valve support 120 can include a metallic,polymeric, or fabric mesh or a woven construction.

Generally, the plurality of posts 122 can extend along an axialdirection generally parallel to the longitudinal axis 101 and the struts124 can extend circumferentially around and transverse to thelongitudinal axis 101. The posts 122 can extend an entire longitudinalheight H₁ of the valve support 120 (FIG. 11A), or in another embodiment,the posts 122 can include a plurality of independent and separate postsegments (not shown) along the valve support height H₁. In oneembodiment the height H₁ can be approximately 14 mm to about 17 mm. Thestruts 124 can form a series of rings around the longitudinal axis 101,wherein each ring has a circumferentially expandable geometry. In theexample shown in FIGS. 11A, 11D and 11E, the struts 124 are formed in aseries of zig-zags and arranged in pairs 180 degrees out of phase witheach other so as to form a series of diamonds. Alternative expandablegeometries can include sinusoidal patterns, chevron configurations (FIG.11B), closed cells (FIG. 11C), open cells, or other expandableconfigurations. The plurality of struts 124 can attach to the pluralityof posts 122 so as to define a plurality of nodes 125 where the strutsand posts intersect. The plurality of struts 124 and the plurality ofposts 122 can be formed from a deformable material or a resilient orshape memory material (e.g., Nitinol).

The anchoring member 110 and the valve support 120 may be made of thesame or, in some embodiments, different materials. In some embodiments,both the anchoring member 110 and the valve support 120 include aresilient biocompatible metal, such as stainless steel, nickel cobalt orcobalt chromium alloys such as MP35N, or nickel titanium alloys such asNitinol. Superelastic shape memory materials such as Nitinol can allowthe device to be collapsed into a very low profile deliveryconfiguration suitable for delivery through the vasculature viacatheter, and allow self-expansion to a deployed configuration suitablysized to replace the target valve. In some embodiments, the anchoringmember 110 and/or the valve support 120 can be laser cut from a singlemetal tube into the desired geometry, creating a tubular scaffold ofinterconnected struts. Anchoring member 110 may then be shaped into adesired configuration, e.g. a flared, funnel-like or hyperboloid shape,using known shape-setting techniques for such materials.

As shown in FIGS. 11B-11E, the valve support 120 has an interior surface126 and an exterior surface 127, and the valve support 120 is configuredto receive or support the prosthetic valve 130 within an interior lumenof the valve support 120 to inhibit retrograde blood flow (e.g., bloodflow from the left ventricle into the left atrium). Accordingly, thevalve support 120 can provide a scaffold to which prosthetic valvetissue can be secured and provide a scaffold that has sufficient axialrigidity to maintain a longitudinal position of the prosthetic valve 130relative to the anchoring member 110. The valve support 120 can furtherprovide such a scaffold having radial rigidity to maintain circularity(or other desired cross-sectional shape) to ensure that leaflets 132 ofthe prosthetic valve 130 coapt or otherwise seal when the device 100 issubject to external radial pressure. In one embodiment, the valvesupport 120 can have a support region 145 along the longitudinal axis101 that is configured to attach to the prosthetic valve, or in otherembodiments, be aligned with the coaptation portion of the leaflets 132(shown in FIG. 11B).

The valve 130 may comprise a temporary or permanent valve adapted toblock blood flow in the upstream direction and allow blood flow in thedownstream direction through the valve support 120. The valve 130 mayalso be a replacement valve configured to be disposed in the valvesupport 120 after the device 100 is implanted at the native mitralvalve. The valve 130 can have a plurality of leaflets 132, and may beformed of various flexible and impermeable materials including PTFE,Dacron®, pyrolytic carbon, or other biocompatible materials or biologictissue such as pericardial tissue or xenograft valve tissue such asporcine heart tissue or bovine pericardium. Other aspects of valve 130are described further below. The interior surface 126 within the lumenof the valve support 120 can be covered at least partially by animpermeable sealing member 140 to prevent blood flow from inside thevalve support 120 to the outside of the valve support 120, where itcould leak around the exterior of the valve support 120. In anotherembodiment, the sealing member 140 may be affixed to the exteriorsurface 127 of the valve support 120 and, in either embodiment, may beintegrally formed with or attached directly to valve 130. In anadditional embodiment, the sealing member 140 can be applied on at leastportions of both the interior surface 126 and the exterior surface 127of the valve support 120.

As shown in FIGS. 11B-11E, the prosthetic valve 130 can be sutured,riveted, glued, bonded, mechanically interlocked, or otherwise fastenedto posts 122 or commissural attachment structures 128, which areconfigured to align with valve commissures C. The posts 122 orcommissural attachment structures 128 can include eyelets 129, loops, orother features formed thereon to facilitate attachment of sutures orother fastening means to facilitate attachment of the prosthetic valve130. In one embodiment, shown in FIG. 11B, the attachment structures 128can be integrated into the structural frame of the valve support 120such that the attachment structures 128 are distributed around thecircumference of the valve support 120 and function as posts 122. Inanother embodiment, shown in FIG. 11D, the attachment structures 128 canbe attachment pads formed on parts of the posts 122 (e.g., along anupper end of the posts 122). In a further embodiment, shown in FIG. 11E,the attachment structures 128 can be separate structures that can becoupled to posts 122, struts 124 or other components along the interiorsurface 126 of the valve support 120.

As illustrated in FIG. 11C, the prosthetic valve 130 may also beattached to the sealing member 140 or sleeve which is attached to theinterior surface 126 of the valve support 120, as described above. Onceattached, the prosthetic valve 130 can be suitable to collapse orcompress with the device 100 for loading into a delivery catheter (notshown). In one embodiment, the prosthetic valve 130 has a tri-leafletconfiguration, although various alternative valve configurations may beused, such as a bi-leaflet configuration. The design of the prostheticvalve 130, such as the selection of tri-leaflet vs. bi-leafletconfigurations, can be used to determine the suitable shape of the valvesupport 120. For example, for a tri-leaflet valve, the valve support 120can have a circular cross-section, while for a bi-leaflet valve,alternative cross-sectional shapes are possible such as oval or D-shapedcross-sections. In particular examples, the valve support can have acircular cross-sectional diameter of approximately 25 mm to about 32 mm,such as 27 mm.

In some arrangements, the valve support 120 can have a permanentprosthetic valve pre-mounted therein, or the valve support 120 may beconfigured to receive a separate catheter-delivered valve followingimplantation of the device 100 at the native mitral valve. Inarrangements where a permanent or replacement valve is desirable, thevalve support 120 can further include a temporary valve pro-mountedwithin the interior lumen. If a period of time between placement of thedevice 100 and further implantation of the permanent prosthetic valve isdesirable, a temporary valve sewn into or otherwise secured within thevalve support 120 can assure regulation of blood flow in the interim.For example, temporary valves may be used for a period of about 15minutes to several hours or up to a several days. Permanent orreplacement prosthetic valves may be implanted within a temporary valveor may be implanted after the temporary valve has been removed. Examplesof pre-assembled, percutaneous prosthetic valves include, e.g., theCoreValve ReValving® System from Medtronic/Corevalve Inc. (Irvine,Calif. USA), or the Edwards-Sapien® valve from Edwards Lifesciences(Irvine, Calif., USA). If adapted to receive a separatecatheter-delivered valve, the valve support 120 may have features withinits interior lumen or on its upper or lower ends to engage and retainthe catheter-delivered valve therein, such as inwardly extending ridges,bumps, prongs, or flaps. Additional details and embodiments regardingthe structure, delivery and attachment of prosthetic valves, temporaryvalves and replacement valves suitable for use with the prosthetic heartvalve devices disclosed herein can be found in International PCT PatentApplication No. PCT/US2012/043636, entitled “PROSTHETIC HEART VALVEDEVICES AND ASSOCIATED SYSTEMS AND METHODS,” filed Jun. 21, 2012, theentire contents of which are incorporated herein by reference.

In some arrangements, the anchoring member 110 is defined by a structureseparate from the valve support 120. For example, the anchoring member110 can be a first or outer frame or skeleton and the valve support 120can be a second or inner frame or skeleton. As such, the anchoringmember 110 can at least partially surround the valve support 120. Insome embodiments, the downstream portion 111 of the anchoring member 110can be coupled to the valve support 120 while the upstream portion 112is not connected or coupled to the valve support 120 in a manner thatunduly influences the shape of the valve support 120. For example, insome embodiments, the upstream portion 112 of the anchoring member 110can be configured to engage and deform to the shape of the native tissueon or under the annulus while the cross-sectional shape of the valvesupport 120 remains sufficiently stable. For example, the valve support120 (e.g., at least at the upstream end 121) can be spaced radiallyinward from the upstream portion 112 of the anchoring member 110 suchthat if the anchoring member 110 is deformed inwardly, at least theupstream end 121 of the valve support 120 remains substantiallyundeformed. As used herein, “substantially undeformed” can refer tosituations in which the valve support 120 is not engaged or deformed, orcan refer to scenarios in which the valve support 120 can deformslightly but the prosthetic valve 130 remains intact and competent(e.g., the leaflets 132 coapt sufficiently to prevent retrograde bloodflow). In such arrangements, leaflets 132 of the prosthetic valve 130can close sufficiently even when the device 100 is under systolicpressures or forces from the pumping action of the heart.

The longitudinal ribs 114 and/or circumferential connectors 116 can beless rigid than the posts 122 and/or struts 124 of the valve support120, allowing greater flexibility in the anchoring member 110 and/ormore stability to the shape and position of the valve support 120. Insome embodiments, the flexibility of the anchoring member 110 can allowthe anchoring member 110 to absorb distorting forces as well as allowthe device 100 to conform to the irregular, non-circular shape of thenative annulus (while leaving the valve support 120 substantiallyunaffected), encouraging tissue ingrowth and creating a seal to preventleaks between the device 100 and the native tissue. In addition, thelongitudinal ribs 114 and/or connectors 116 can be configured to pressradially outward against the native valve, ventricular and/or aorticstructures so as to anchor the device 100 in a desired position, as wellas maintain an upstream deployed circumference 150′ larger than that ofthe native annulus such that subannular positioning effectively preventsupstream migration of the device 100 (described further below in FIG.14C). Furthermore, the longitudinal ribs 114 can have sufficientresilience and column strength (e.g., axial stiffness) to preventlongitudinal collapse or eversion of the anchoring member 110 and/or thedevice 100 and to resist movement of the device in an upstreamdirection.

By structurally separating the anchoring member 110 from the valvesupport 120, the valve 130 and valve support 120 are effectivelymechanically isolated from the distorting forces exerted on theanchoring member 110 by the native tissue, e.g., radially compressiveforces exerted by the native annulus and/or leaflets, longitudinaldiastolic and systolic forces, hoop stress, etc. For example,deformation of the anchoring member 110 by the native tissue can changea cross-section of the anchoring member 110 (e.g., to a non-circular ornon-symmetrical cross-section), while the valve support 120 may besubstantially undeformed. In one embodiment, at least a portion of thevalve support 120 can be deformed by the radially compressive forces,for example, where the anchoring member 110 is coupled to the valvesupport 120 (e.g., the downstream end 123). However, the upstream end121 of the valve support 120 and/or the valve support region 145 (FIG.11B) is mechanically isolated from the anchoring member 110 and thecompressive forces such that at least the valve support region 145 canbe substantially undeformed. Thus the valve support 120, and at leastthe valve support region 145, can maintain a circular or other desirablecross-section so that the valve remains stable and/or competent. Theflexibility of the longitudinal ribs 114 can contribute to theabsorption of the distorting forces, and also aid in mechanicallyisolating the valve support 120 and valve 130 from the anchoring member110.

At an upstream end of the device 100 oriented toward the left atrium,the valve support 120 can be configured to sit below, even with, orabove the uppermost terminal of the upstream portion 112 of theanchoring member 110. At a downstream end of the device 100 orientedtoward and residing within the left ventricle, the anchoring member 110can be coupled to the valve support 120. Alternatively, the anchoringmember 110 can be coupled to the valve support 120 anywhere along alength of the valve support 120. The valve support 120 and anchoringmember 110 may be coupled by a variety of methods known in the art,e.g., suturing, soldering, welding, staples, rivets or other fasteners,mechanical interlocking, friction, interference fit, or any combinationthereof. In other embodiments, the valve support 120 and the anchoringmember 110 can be integrally formed with one another. In yet anotherembodiment, a sleeve or other overlaying structure (not shown) may beattached to both the anchoring member 110 and the valve support 120 tointerconnect the two structures.

FIGS. 12A-12C are side views of various longitudinal ribs 114 flexing inresponse to a distorting force F in accordance with further embodimentsof the present technology. The degree of flexibility of individuallongitudinal ribs 114 (and thus the anchoring member 110) may beconsistent among all ribs of an anchoring member 110, or, alternatively,some ribs 114 may be more flexible than other ribs 114 within the sameanchoring member 110. Likewise, a degree of flexibility of individualribs 114 may be consistent throughout an entire length of the rib 114 orthe degree of flexibility can vary along the length of each rib 114.

As shown FIGS. 12A-12C, the longitudinal ribs 114 (shown individually as114A-114C) may flex along their respective lengths in response todistorting forces F that can be applied by the surrounding tissue duringor after implantation of the device 100. In FIG. 12A, the rib 114A mayflex downward to a position 75′ or upward to a position 75″ in responseto an upward or downward force F₁, respectively. Similarly, in FIG. 12B,a rib 114B with multiple distinct segments 85A, 85B, 85C may flex and/orrotate inwardly/outwardly or side-to-side in response to alaterally-directed force F₂. The distinct segment 85A at the end of therib 1148 may flex and/or rotate inwardly/outwardly or side-to-side(e.g., to position 85A′) in response to the laterally directed force F₂separate from lower distinct segments 85B and 85C. In otherarrangements, the segment 85A may flex and/or rotate (e.g., to position85AB′) with the distinct segment 85B or with both segments 85B and 85Ctogether (not shown). As shown in FIG. 12C, the rib 114C having agenerally linear shape when in a relaxed state, may also flex and/orrotate inwardly/outwardly or side-to-side (e.g., to positions 95′ or95″) in response to a laterally-directed force F₃, by bending to createa curved shape, or in another embodiment not shown, by bending so as tocreate two substantially linear segments.

Individual ribs 114 can also have a variety of shapes and be placed in avariety of positions around a circumference of the anchoring member 110.In some embodiments, the device 100 can include a first and secondplurality of ribs wherein the first plurality of ribs have acharacteristic different than the second plurality of ribs. Variouscharacteristics could include size of the rib, rib shape, rib stiffness,extension angle and the number of ribs within a given area of theanchoring member. In other embodiments, the longitudinal ribs can beunevenly or evenly spaced around an outer perimeter of the anchoringmember,

The ribs 114 can be positioned around a circumference oriented along thelongitudinal axis 101 of the anchoring member 110 to create any numberof overall cross-sectional geometries for the anchoring member 110,e.g., circular, D-shaped, oval, kidney, irregular, etc. FIG. 13A is aschematic, cross-sectional view of a prosthetic heart valve device inaccordance with another embodiment of the present technology, and FIGS.13B-13F are partial side views of prosthetic heart valve devicesillustrating a variety of longitudinal rib configurations in accordancewith additional embodiments of the present technology. Referring to FIG.13A, an individual rib 114 can comprise a plurality of linear segments,such as segments 85A and 85B. In the illustrated example, the ribsegment 85B is angled radially outwardly (e.g., angled away from thelongitudinal axis 101) by a first angle A₁. The rib segment 85B extendsin an upstream direction from its point of attachment to the valvesupport 120 at the downstream end of the segment 85B, thereby giving theanchoring member 110 a conical or flared shape, with a larger diameterD₂ at the upstream portion 112 and a smaller diameter D₃ at thedownstream portion 112 of the anchoring member 110. In one embodiment,the upper rib segment 85A can be angled at a steeper second angle A₂relative to the longitudinal axis 101 than lower rib segment 85B,resulting in a wider flared upstream portion 112A at the upstreamportion 112 of the anchoring member 110. In some arrangements, the widerflared upstream portion 112A may enhance sealing between the anchoringmember 110 and the native tissue, while the downstream portion 111 canprovide a more rigid geometry for resisting upstream movement of thedevice 100 when systolic forces are exerted on the device 100.Alternatively, the rib 114 can be arcuate over all or a portion of itslength, as shown in the partial side view of FIG. 13B.

In yet other embodiments, as illustrated by FIGS. 13C-13F, the rib 114can have a more complex shape defined by multiple distinct segments 85A,85B, 85C, etc. For example, as shown in FIG. 13C, the rib 114 includes alinear rib segment 85C generally parallel to the longitudinal axis 101connected at its upstream end to a linear and radially outwardlyextending rib segment 85B, where rib segment 85B is connected at itsupstream end to a more vertical rib segment 85A which is about parallelwith the longitudinal axis 101. Referring to FIG. 13D, the rib 114 caninclude a linear rib segment 85B generally parallel to longitudinal axis101 and connected at its upstream end to a linear and radially outwardlyextending rib segment 85A, which is generally perpendicular tolongitudinal axis 101. Referring to FIG. 13E, the rib 114 can include alinear rib segment 85C generally parallel to the longitudinal axis 101and connected at its upstream end to a linear and radially outwardlyextending rib segment 85B which is generally perpendicular to thelongitudinal axis 101. The rib segment 85B can further be connected atits most radially outward end to a vertical rib segment 85C generallyparallel with the longitudinal axis 101. In reference to FIG. 13F, therib 114 includes a linear segment 85D generally parallel with thelongitudinal axis 101 and connected at its upstream end to a radiallyoutwardly extending segment 85C which is generally perpendicular to thelongitudinal axis 101. The rib segment 85C can further be connected atits most radially outward end to a linear, vertical segment 85Bgenerally parallel with the longitudinal axis 101, and where 85B isconnected at its most radially outward end to a linear and radiallyinward extending segment 85A.

In the embodiments illustrated in FIGS. 13C-13F, the ribs 114 can becoupled to the valve support 120 (e.g., coupled to posts 122) in amanner to enhance mechanical isolation of the valve support 120. Forexample, the ribs 114 may be attached to the valve support 120 near thedownstream end of the ribs 114 such that a substantial portion of eachrib 114 upstream of the attachment point is movable and deformablerelative to the valve support 120, thereby allowing the rib 120 to flexradially outward or circumferentially back and forth relative to thevalve support 120. Additionally, one of ordinary skill in the art willrecognize that in any of the embodiments illustrated in FIG. 13A-13F,any or all of the rib segments may have a curvature, and anyinterconnections of segments shown as angled may instead be curved.Accordingly, any of these various geometries may be configured to allowthe anchoring, member 110 to conform to the native anatomy, resistmigration of the device 100, and mechanically isolate the valve support120 and/or the prosthetic valve 130 contained therein from forcesexerted on the anchoring member 110 by the native tissue.

The flexible characteristics of the individual ribs 114 can allow forthe flexibility and conformability of the anchoring member 110 to engageand seal the device 100 against uneven and uniquely-shaped nativetissue. Additionally, the flexibility can assist in creating a sealbetween the device 100 and the surrounding anatomy. FIG. 14A is aschematic top view of a native mitral valve MV illustrating the minoraxis 50 and major axis 55, and FIGS. 14B-14C are schematic top views ofan anchoring member 110 in an expanded configuration 102 and in adeployed configuration 104, respectively, overlaying the schematic ofthe native mitral valve MV in accordance with an embodiment of thepresent technology.

Referring to FIG. 14B, the upstream portion 112 (FIG. 10A) of theanchoring member 110 can have an outer circumference 150 with a diameterD₁ that is greater than the minor axis 50 (FIG. 14A) of the nativeannulus, and usually less than the major axis 55 of the annulus, whenthe anchoring member 110 is in an expanded configuration 102 (shown asdashed lines). In other embodiments, the anchoring member 110 may have adiameter D₁ at least as large as the distance between the nativecommissures C, and may be as large as or even larger than the major axis55 of the native annulus. In some embodiments, the outer circumference150 of the anchoring member 110 has the diameter D₁ which isapproximately 1.2 to 1.5 times the diameter (not shown) of the valvesupport 120 (or the prosthetic valve 130), and can be as large as 2.5times the diameter of the valve support 120 (or the prosthetic valve130). While conventional valves must be manufactured in multiple sizesto treat diseased valves of various sizes, the valve support 120 and theprosthetic valve 130, in accordance with aspects of the presenttechnology, may be manufactured in just a single diameter to fit amultitude of native valve sizes. For example, the valve support 120 andthe prosthetic valve 130 do not need to engage and fit the nativeanatomy precisely. In a specific example, the valve support 120 may havea diameter (not shown) in the range of about 25 mm to about 32 mm foradult human patients. Also in accordance with aspects of the presenttechnology, the anchoring member 110 may be provided in multiplediameters to fit various native valve sizes, and may range in diameterat an upstream end from about 28 mm to about 80 mm, or in otherembodiments, greater than 80 mm.

The top view of the anchoring member 110 shown in FIG. 14C illustrateshow flexibility and/or deformation of one or more longitudinal ribs 114and/or rib segments allows the anchoring member 110 to distort relativeto the expanded configuration 102, as shown by the dashed lines, into adeployed configuration 104, as shown by the bolded lines. As shown inFIG. 14C, the anchoring member 110, when deployed or implanted at orunder the mitral valve annulus, can conform to the highly variablenative mitral valve tissue shape MV, as shown in the dotted lines, whilethe ribs 114 bend, twist, and stretch such that the overall shape of theanchoring member 110 has a deployed (e.g., a generally more oval orD-shaped, or other irregular shape) configuration 104 instead of a fullyexpanded configuration 102. Referring to FIGS. 14B-14C together, theanchoring member 110 covers the mitral valve commissures C in thedeployed configuration 104, whereas the commissures C would be leftunsealed or exposed in the more circular expanded configuration 102,potentially allowing paravalvular leaks. The anchoring member 110 couldalso be pre-shaped to be in a generally oval or D-shape, or other shape,when in an unbiased condition.

FIG. 15 is an isometric view of an embodiment of the prosthetic heartvalve device 100 illustrated in a deployed configuration 104 inaccordance with an embodiment of the present technology. FIG. 15illustrates the device 100 having a plurality of ribs 114, wherein afirst set of ribs 160 can be configured to bend inwards or compresstoward the center longitudinal axis 101 of the device 100 and a secondset of ribs 162 can be configured to bend outwards or flex in responseto an distorting forces present in a subannular space of the nativevalve. As a result, the outer circumference 150 of the anchoring member110 may distort from a more circular shape in the expanded configuration102, as shown by the dashed line, to a generally more oval or D-shape inthe expanded configuration 104, as shown by the solid line, thusconforming to the shape of the native anatomy. In a further arrangement,the upstream portion 112 of the anchoring member 110 may be sizedslightly larger than the subannular space into which it is deployed,such that the anchoring member 110 is compressed to a slightly smallerdiameter in its deployed configuration 104. This may cause a slightrelaxation of the scaling member 142, such that sealing member sectionsbetween adjacent ribs 114 are sufficiently slack to billow or curveinwards or outwards to form a slack section Bi, as shown in FIG. 15.Such billowing can be desirable in some arrangements because thecurvature of the relaxed sleeve segment Bi can engage and conform to themitral leaflet tissue, thereby enhancing a seal formed between thedevice 100 and the native tissue.

As shown in FIG. 15, the unbiased, expanded configuration of the valvesupport 120, which in the illustrated embodiment is circular incross-section, remains substantially unaffected while the anchoringmember 110 conforms to the non-circular shape of the native mitral valveannulus MV. Accordingly, the valve support 120 is mechanically isolatedfrom these forces and maintains its structural shape and integrity. Themechanical isolation of the valve support 120 from the anchoring member110 may be attributed to several aspects of the prosthetic heart valvedevice 100. For example, the relative high flexibility of the anchoringmember 110 compared with the lower flexibility of the valve support 120allows the anchoring member 110 to deform significantly when deployedand when in operation (e.g., conform to the shape and motion of theanatomy under ventricular systole forces) while the valve support 120remains substantially undeformed (e.g., generally circular) in thesesame conditions. Additionally, radial spacing between the anchoringmember 110 and the valve support 120, particularly at the upstreamportion/upstream end when the anchoring member 110 engages the nativeannulus and/or subannular tissue, allows the anchoring member 110 to bedeformed inwardly a substantial amount without engaging the valvesupport 110. Further, the anchoring member 110 can be coupled to thevalve support 120 at a location (e.g. the downstream portion 111 of theanchoring member 110) which is spaced apart longitudinally a substantialdistance from the location (e.g., the upstream portion 112 of theanchoring member 110) at which the anchoring member 110 engages thenative annulus, allowing the ribs 114 of the anchoring member 110 toabsorb much of the distorting forces exerted upon it rather thantransmitting those forces directly to the valve support 120. Moreover,the coupling mechanisms employed to attach the anchoring member 110 tothe valve support 120 can be configured (e.g., to be flexible ormoveable) so as to reduce the transmission of forces from the anchoringmember 110 to the valve support 120 (discussed in more detail herein).

In many embodiments, the anchoring member 110 can have sufficientflexibility such that the anchoring member 110 conforms to the nativemitral annulus when in the deployed configuration 104 (FIGS. 14C and15); however, the anchoring member 110 can be configured to remainbiased towards its expanded configuration 102 (e.g., FIGS. 10A and 14B)such that, when in the deployed configuration 104, the anchoring member110 pushes radially outwards against the native annulus, leaflets,and/or ventricular walls just below the annulus. In some arrangements,the radial force generated by the biased anchoring member shape may besufficient to deform the native anatomy such that the minor axis 50(FIG. 14A) of the native valve is increased slightly, and/or the shapeof the annulus is otherwise altered. Such radial force can enhanceanchoring of the device 100 to resist movement toward the atrium whenthe valve 130 is closed during ventricular systole as well as movementtoward the ventricle when the valve 130 is open. Furthermore, theresulting compression fit between the anchoring member 110 and leafletsand/or ventricular walls or other structures helps create a long-termbond between the tissue and the device 100 by encouraging tissueingrowth and encapsulation.

FIGS. 16A-17C illustrate a prosthetic heart valve device 100 configuredin accordance with additional embodiments of the present disclosure.FIGS. 16A-16C include a top view and first and second side views of aprosthetic heart valve device 100 illustrated in an expandedconfiguration 102 that includes features generally similar to thefeatures of the prosthetic heart valve device 100 described above withreference FIGS. 10A-15. For example, the device 100 includes the valvesupport 120 and the prosthetic valve 130 housed within an interior lumenof the valve support 120. However, in the embodiment shown in FIGS.16A-16C, the device 100 includes an anchoring member 210 having an ovalor D-shaped upstream perimeter 213 and a plurality of elevations arounda circumference 250 of the anchoring member 210 such that the anchoringmember 210 is suitable for engaging and conforming with tissue in thesubannular region of the mitral valve.

Referring to FIGS. 16A-16C together, the device 100 can include theflexible anchoring member 210 at least partially surrounding and coupledto the valve support 120 at a downstream portion 211 of the anchoringmember 210. The device 100 can also include one or more sealing members140 extending around an inner wall 241 of the anchoring member 210and/or around the exterior surface 127 or the interior surface 126 ofthe valve support 120 to prevent paravalvular leaks between the device100 and the native tissue and/or between the anchoring member 210 andthe valve support 120. In one embodiment, the sealing member 140 canwrap around and/or cover the upstream perimeter 213 of the anchoringmember 210. For example, the sealing member 140 can be sewn, sutured, oradhered to a wall 241, 242 and have an extended portion (not shown) thatfolds over the upstream perimeter 213. In one embodiment, the sealingmember 140 can be adhered to an opposite wall (e.g., extend from theinner wall 241 to cover the upstream perimeter 213 and attached to anupper portion of the outer wall 242). However, in other embodiments, thescaling member 140 can have a longer free edge (not shown) leftunattached. The free edge of the sealing member 140 can be suitable insome arrangements to inhibit blood flow between the upper perimeter 213and the native tissue.

As illustrated in FIGS. 16B-16C, the anchoring member 210 has thedownstream portion 211 and an upstream portion 212 opposite thedownstream portion 111 along a longitudinal axis 201 of the device 100.Similar to the anchoring member 110 of device 100 (FIG. 10A), theupstream portion 212 of the anchoring member 210 can be a generallyoutward oriented portion of the device 100. In some embodiments, theanchoring member 110 can include of a series of circumferentiallypositioned, resiliently deformable and flexible ribs 214 which can be ina crisscross pattern around the circumference 250 of the anchoringmember 210 to form a diamond pattern. In one embodiment, the ribs 214can be flexible wires or filaments arranged in a diamond pattern orconfiguration. The diamond configuration, in some embodiments, provideshoop strength sufficient to provide a frictional attachment to thenative annulus and leaflet tissue to inhibit movement of the device 100relative the annulus under the force of systolic blood pressure againstthe valve 130 mounted in the valve support 120. In a particular example,the anchoring member 120 can be formed of a preshaped Nitinol tubehaving, for example, a wall thickness of approximately 0.010 inches toabout 0.030 inches. The diamond pattern or configuration can, forexample, include one or more rows of diamonds, and in some embodiments,between approximately 12 and approximately 36 columns of diamonds aroundthe circumference 250 of the anchoring member 210.

In some embodiments, the upstream perimeter 213 of the anchoring member210 does not lie in a single plane. For example, the ribs 214 can havevariable lengths and/or be off-set from each other at variable anglessuch that a distance (e.g., elevation) between a downstream perimeter215 and the upstream perimeter 213 can vary around the circumference250. For example, the upstream perimeter 213 can form a rim having aplurality of peaks 251 and valleys 252 (FIG. 16B) for adapting to theshape of the native mitral valve (see FIG. 5C). As used herein, “peaks”and “valleys” do not refer to diamond peaks and diamond valleys of adiamond pattern formed by the plurality of ribs 214, but refers toportions of the upstream perimeter 213 having an undulating shape formedby changes in elevation with respect to the downstream perimeter 215. Inone embodiment, the distance between the downstream perimeter 215 andthe upstream perimeter (e.g., elevation) can vary from about 6 mm toabout 20 mm, and in another embodiment, between about 9 mm and about 12mm.

In one embodiment, the upstream perimeter 213 of the anchoring member210 can have two peaks 251 that are separated by two valleys 252. Insome embodiments, a first peak can have a different shape or elevationthan that of a second peak. In other embodiments, the shape of a valley252 can be different than a shape of an inverted peak 251. Accordingly,the peaks 251 and valleys 252 can be asymmetrically positioned andshaped around the circumference 250 of the anchoring member 210. Invarious arrangements, the valleys 252 can be configured for positioningalong commissural regions of the native annulus, and the peaks 251 canbe configured for positioning along leaflet regions of the nativeannulus. In one embodiment, the peaks 251 can have apices configured tobe positioned near midpoint regions of the leaflets. The anchoringmember might also be circumferentially symmetric when in theunconstrained position, but form the aforementioned “peaks and valleys”when deployed in a non-circular annulus, so that the more radiallyexpanded portions, typically corresponding to the commissures, are lowerthan the less expanded areas, near the centers of the leaflets. Such aneffect might be facilitated by the specific geometry of the ribs anddiamond patterns of the anchoring member.

Referring to FIGS. 17A-17C, one specific example of the anchoring member210 can have a first elevation E₁ between the downstream perimeter 215and the upstream perimeter 213 of approximately 7 mm to about 8 mm atfirst and second regions 253, 254 of the anchoring member. The first andsecond regions 253, 254 are configured to align with the first andsecond commissures (e.g., anterolateral commissure AC and posteromedialcommissure PC, FIG. 5A) of the native mitral valve. The anchoring member210 can also have a second elevation E₂ between the downstream perimeter215 and the upstream perimeter 213 of approximately 9 mm to about 11 mmat a third region 255 of the anchoring member 210, wherein the thirdregion 255 is configured to align with an anterior leaflet AL (FIG. 5A)of the native mitral valve. The anchoring member 210 can further have athird elevation E₃ between the downstream perimeter 215 and the upstreamperimeter 213 of approximately 12 mm to about 13 mm at a fourth region256 of the anchoring member 210 opposite the third region 255, whereinthe fourth region 256 is configured to align with a posterior leaflet PL(Figure SA) of the native mitral valve. One of ordinary skill in the artwill recognize that the elevations E₁, E₂ and E₃ can have othermeasurements, and in some embodiments, the elevations E₁, E₂ and E₃ canbe different from one another or the same.

Additionally, the upstream perimeter 213 can form a rim having agenerally oval or D-shape, or other irregular shape for adapting to theshape of the native mitral valve. For example, and referring to FIG.17A, the upstream perimeter 213 of the anchoring member 210 can have amajor perimeter diameter D_(m1) and a minor perimeter diameter D_(m2)perpendicular to the major perimeter diameter D_(m1). In one embodiment,the major perimeter diameter D_(m1) is greater than the long axis MVA1of the native mitral valve (shown in FIG. 5C) when the device 100 is inthe expanded configuration 102 (FIG. 17A). In another embodiment, themajor perimeter diameter D_(m1) is less than the long axis MVA1 when thedevice 100 is in the expanded configuration 102. In such embodiments,the device 100 can be configured to have a major perimeter diameterD_(m1) that is greater than the long axis MVA1 when the device is in thedeployed configuration (e.g., when engaging the tissue on or under thenative annulus, see FIG. 16E). Further, the minor perimeter diameterD_(m2) can be greater than the short axis MVA2 of the native mitralvalve (shown in FIG. 5C) when the device 100 is in the expandedconfiguration 102 (FIG. 17A), or alternatively in the deployedconfiguration (FIG. 16E). In one embodiment, the major perimeterdiameter D_(m1) and/or minor perimeter diameter D_(m2) can beapproximately 2 mm to approximately 22 mm, or in another embodiment,approximately 8 mm to approximately 15 mm greater than the long axisMVA1 and/or the short axis MVA2, respectively, of the native mitralvalve. In some embodiments, the major perimeter diameter can beapproximately 45 mm to about 60 mm and the minor perimeter diameter canbe approximately 40 mm to about 55 mm.

Again referring to FIG. 16C, the upstream portion 212 of the anchoringmember 210 can be radially separated from the valve support 120 by a gap257. In one embodiment, the gap 257 is greater on an anterior leafletfacing side of the device 100 (e.g., along the third region 255) than ona posterior leaflet-facing side of the device 100 (e.g., along thefourth region 256).

Referring back to FIGS. 16A and 16C, the valve support 120 can beoriented along the first longitudinal axis 101 and the anchoring member210 can be oriented along the second longitudinal axis 201. The secondlongitudinal axis 201 can be off-set from the first longitudinal axis101. “Off-set” can refer to an arrangement where the axes 101, 201 areparallel but separated such that the gap 257 can vary around thecircumference 250 (FIG. 16C). FIG. 16D shows another embodiment in which“off-set” can refer to an arrangement wherein the second axis 201 can beangled from the first axis 101 (e.g., the first and second 101, 201 axesare non-collinear or non-parallel) such that the anchoring member 210 isgenerally tilted with respect to the valve support 120. In oneembodiment, the second longitudinal axis 201 is disposed at a tilt angleA_(TL) between 15° and 45° relative to the first longitudinal axis 101.

In additional embodiments, and as shown in more detail in FIG. 18, thefirst and second regions 253 and 254 of the upstream perimeter 213 canextend further from the longitudinal axis 201 than the third 255 andfourth regions 256. For example, the anchoring member 210 can have agenerally conical body (shown in dotted lines) and have upstream rimextensions 258 in the first and second regions 253 and 254. In someembodiments, the third region 255 of the upstream perimeter 213 canextend further from the longitudinal axis 201 than the fourth region256. In some arrangements, the third region 255 can have a size andshape that allows the anchoring member 210 to engage the inward facingsurface of the anterior leaflet without substantially obstructing theleft ventricular outflow tract (LVOT).

Referring to FIGS. 17A-17C together, the valve support 120 can beoriented along the longitudinal axis 101, and the upstream portion 212of the anchoring member 210 can flare outward from the longitudinal axis101 by a taper angle A_(T). In embodiments where the ribs 214 aregenerally curved outward from the downstream portion 211 to the upstreamportion 212 (rather than linear), the taper angle A_(T) can continuouslychange between the downstream portion and the upstream portion. In someembodiments, the taper angle A_(T) can be the same around thecircumference 250 of the upstream portion 212 of the anchoring member210; however, in other embodiments, the taper angle A_(T) can varyaround the circumference 250. For example, the anchoring member 210 canhave a first taper angle A_(T1) at the first and second regions 253 and254 (FIG. 17B) which can be configured to align with the anterolateralcommissure AC and posteromedial commissure PC (see FIG. 5C),respectively. The anchoring member 210 can further have a second taperangle A_(T2) at the third region 255 which can be configured to alignwith the anterior leaflet, and a third taper angle A_(T3) at the fourthregion 256 which can be configured to align with the posterior leaflet(FIG. 17C). In one embodiment, the taper angle can be approximately 30°to about 75°, and in another embodiment, between approximately 40° andabout 60°.

One important aspect of having asymmetric rib lengths for the anchoringmembers is that different lengths might mean that one side or segment ofthe anchoring member is exposed from the delivery system before theothers, allowing the physician deploying the device to optimize theorientation of the device prior to full deployment.

These variations in shaping of the anchoring member can serve severalfunctions. One is to ensure a better fit with the native valve annulus.Another is to optimize the bending load on each rib and section of theanchoring member in the deployed position, in part to minimize long-termfatigue stresses on the ribs. A third reason is to ensure that theanchoring member, when deployed in the mitral annulus, does not impartasymmetric forces on the valve support member. A fifth is to reduce theforce of the deployed device against the anterior leaflet, so theleaflet isn't excessively displaced towards the aortic valve. By makingsure that the middle of the anterior leaflet is less radially expanded,the radius of curvature of the circumference of the anchoring memberwill be higher in that area, and per Laplace's law, the radial force ofthat area will be lower.

FIG. 16E is a schematic top view of a native mitral valve in the heartviewed from the left atrium and showing the prosthetic treatment device100 of FIG. 16A-16C implanted at the native mitral valve MV inaccordance with an embodiment of the present technology. Once deployed,and as illustrated in FIG. 16E, at least a portion of the upstream endsof the ribs 214 (shown in FIGS. 16B-16C) engage a subannular surface ofthe native valve (e.g., mitral valve). As described in more detailbelow, certain embodiments of ribs 114 or 214 are configured topenetrate subannular tissue to anchor and further stabilize the devices100.

Although the anchoring member 210 is deformable in response todistorting forces exerted by the native anatomy, the valve support 120can have sufficient rigidity to maintain a circular or other originalcross-sectional shape, thus ensuring proper functioning of theprosthetic valve leaflets 132 when opening and closing. Such mechanicalisolation from the anchoring member 210 may be achieved by the valvesupport 120 having sufficient rigidity to resist deformation whileanchoring member 210 is deformed, and by selecting a location and meansfor coupling the valve support 120 to the anchoring member 210 so as tomitigate the transmission of forces through the anchoring member 210 tothe valve support 120 or the prosthetic valve 130 contained therein. Forexample, the valve support 120 may be coupled to the anchoring member210 only at the downstream end 123 of the valve support 120, which isseparated from the upstream end 121 where the anchoring member 210engages the annulus. On the upstream end 121 of the anchoring member210, the valve support 120 may be completely unconnected to and spacedradially apart from the anchoring member 210 by the gap 257 to allowdeformation of the anchoring member 210 without impacting the shape ofvalve support 120 (see FIGS. 16A-16C where the prosthetic valve 130 islocated). Thus, forces exerted on the anchoring member 210 by theannulus can be absorbed by the flexible ribs 214 of the anchoring member210 to mitigate transmission of such forces to the downstream end 123 ofvalve support 120.

In some embodiments, it may be desirable to limit a distance the device100 extends downstream of the annulus into the left ventricle (e.g., tolimit obstruction of the left ventricle outflow tract (LVOT)).Accordingly, some embodiments of the device 100 can include anchoringmembers 210 having a relatively low overall elevation (e.g., elevationsE₁, E₂ and E₃. FIGS. 17B-17C), such that the anchoring member 210 doesnot extend into or obstruct the LVOT. As shown in the side view of FIG.16B, for example, the anchoring member 110 can have a low overallelevation E_(L) (e.g., the distance between the upstream perimeter 213and the downstream perimeter 215 of the anchoring member 210) withrespect to a height H_(V) of the valve support 120. In such embodiments,the upstream perimeter 213 of the anchoring member 110 may be justbelow, adjacent to, or positioned within the annulus of the nativemitral valve while the downstream perimeter 215 of the anchoring member210 is configured to extend minimally into the left ventricle below thenative mitral valve annulus when the device 100 is implanted. In somearrangements, the valve support 120 can be coupled to anchoring member210 so as to also minimize protrusion into the left ventricle, and insome embodiments, may extend upwardly through the plane of the nativeannulus into the left atrium.

Additional Components and Features Suitable for Us with the ProstheticHeart Valve Devices

Additional components and features that are suitable for use with theprosthetic heart valve devices (e.g., devices 100 described above) aredescribed herein. It will be recognized by one of ordinary skill in theart that while certain components and features are described withrespect to a particular device (e.g., device 100), the components andfeatures can also be suitable for use with or incorporated with otherdevices as described further herein.

As discussed above with respect to FIG. 10A, some embodiments of theprosthetic heart valve device 100 can include a sealing member 140 thatextends around portions of the anchoring member 110 and/or the valvesupport 120. For example, the embodiment illustrated in FIG. 10A has asealing member 140 around the inner wall 141 of the anchoring member 110and around an exterior surface 127 of the valve support 120 to preventparavalvular leaks both between the device 100 and the anatomy but alsothrough components of the device 100.

FIGS. 19A-19C are isometric, side and top views, respectively, of aprosthetic heart valve device 100 having a sealing member 140 inaccordance with a further embodiment of the present technology.Referring to FIGS. 19A-19C together, the device 100 includes a sealingmember 140, such as a skirt 144. The skirt 144 can be disposed on theouter wall 142 or disposed on the inner wall 141 and at least partiallyover the upstream perimeter 113 of the anchoring member 110.Accordingly, the skirt 144 can be fixed and/or coupled to any surface ofthe anchoring member 110. The skirt 144 can also overlay an interiorsurface 126 (shown in FIG. 19A) and/or exterior surface 127 of the valvesupport 120. Variations of the skirt 144 and/or other sealing members140 can be configured to (1) create a blood flow-inhibiting seal betweenthe anchoring member 110 and the native tissue, (2) block blood flowthrough the walls 141, 142 of the anchoring member 110 and/or throughthe surfaces 126, 127 of the valve support 120, and (3) block blood flowthrough the space between the valve support 120 and the anchoring member110. In some embodiments, the sealing member 140 can be configured topromote in-growth of adjacent tissue. The sealing member 140 can help toseal between the anchoring member 110 and the valve support 120, as wellas between the device 100 and the surrounding anatomy such that bloodflow is restricted to flowing through the prosthetic valve 130 from theleft atrium to the left ventricle. Additionally, the sealing member 140can provide circumferential support for the anchoring member 110 when inthe expanded configuration 102 (FIGS. 10A, 16A and 19A) or deployedconfiguration 104 (FIGS. 10B and 16B). In some embodiments, the sealingmember 140 may further serve to attach the anchoring member 110 to thevalve support 120. For example, the skirt 144 can be coupled to theinner wall 141 of the anchoring member 110 and integrally formed with orotherwise attached to the sealing member 140 that is coupled to thevalve support 120. In other embodiments, the sealing member 140 can beused to couple the valve support 120 to the prosthetic valve 130 housedin the interior of the valve support 120. Scaling members 140, such asskirts 144, can be coupled to the anchoring member 110 and/or valvesupport 120 with sutures, rivets or other known mechanical fasteners. Inother embodiments, adhesives, glues and other bonding materials can beused to couple the sealing members to components of the device 100.

FIG. 20A is an isometric view of a prosthetic heart valve device 100without a sealing member 140, and FIGS. 20B-20E are isometric views ofprosthetic heart valve devices 100 having sealing members 140 inaccordance with additional embodiments of the present technology. Forexample, FIGS. 20B-20C show embodiments of the device 100 in which thesealing member 140 is a sleeve 146. The sleeve 146 can include animpermeable sealing material that is cylindrical and configured to fitwithin or over various frame or skeleton structures of the device 100 asfurther described below. In FIG. 20B the sleeve 146 is on the exteriorsurface 127 of the valve support 120, whereas in FIG. 20C, the sleeve146 is also disposed on the inner wall 141 of the anchoring member 110and on the exterior surface 127 of the valve support 120. FIG. 20Dillustrates an embodiment of the device 100 in which the sleeve 146 isdisposed on the outer wall 142 of the anchoring member 110 and on theexterior surface 127 of the valve support 120. Referring to FIG. 20E,the device 100 can also incorporate the sleeve 146 on both the outerwall 142 and inner wall 141 of the anchoring member 110 as well as onthe exterior surface 127 of the valve support 120.

One of ordinary skill in the art will recognize that the sealing members140, such as the skirts 144 and sleeves 146 shown in FIGS. 19A-20E, canfully cover the walls 141, 142 or surfaces 126, 127, or in otherembodiments, at least partially cover the walls 141, 142, and/or thesurfaces 126, 127 of the anchoring member 110 and the valve support 120,respectively. Any combination of sealing members 140 is contemplated.Additionally, the sealing member 140 can comprise a single continuoussheet of fluid impervious material (e.g., for covering the inner surface141 of the anchoring member 110 and the exterior surface 127 of thevalve support 120), which could create a seal between the anchoringmember 110 and the valve support 120. In various embodiments, thesealing member 140, such as the skirt 144 or sleeve 146, can comprise afabric or other flexible and biocompatible material such as Dacron®,ePTFE, bovine pericardium, or other suitable flexible material tointegrate with tissue and minimize paravalvular leaks. In otherembodiments, the sealing member 140 can include a polymer, thermoplasticpolymer, polyester, Gore-tex®, a synthetic fiber, a natural fiber orpolyethylene terephthalate (PET). The valve 130 may also be attached tothe sealing member 140 or integrally formed with the sealing member 140.

In a further embodiment, shown in FIGS. 21A-21F, the valve support 120may comprise a tubular member 148 of fabric, polymer, or pericardiumwith little or no metallic or other structural support. Referring toFIGS. 21A-21B, the tubular member 148 may be a thicker and more rigidportion of a sleeve 146 which is capable of retaining its shape and hassufficient strength to resist radial and axially tensile forces duringsystole, and axial compressive forces during diastole. The leaflets 132of the prosthetic valve 130 may be integrally formed with, sewn orotherwise attached to the tubular member 148. In one embodiment, thetubular member 148 can be integrally formed with an outer portion 146Aof the sleeve 146 that extends around the anchoring member 110 (shown inFIG. 21A), or in another embodiment, the tubular member 148 can be aseparate and/or thicker member which is sewn, bonded, or otherwisefastened to the sleeve 146 in a blood-tight manner. The tubular member148 can optionally include reinforcing members to give it greaterstrength and to help it retain a desirable shape suitable for operatingthe valve 130. For example, a series of relatively stiff longitudinalstruts 190 of metal or polymer can be coupled to or embedded within thewalls of tubular member 148 (FIG. 21C), and/or a wire coil 192 mayextend around or be embedded within walls of the tubular member 148(FIG. 21D). In a further embodiment, a series of tethers 194 can becoupled between the outer portion 146A of the sleeve 146 and tubularmember 148 (FIG. 21E). In one arrangement, the tethers 194 can extend ata downstream angle from the upstream portion 112 of the anchoring member110 so as to inhibit collapse or structural compromise of the tubularmember 148 during atrial systole. In yet another embodiment, a pluralityof vertical septa 196 may be interconnected between the anchoring member110 (and/or a sealing member 140 coupled to the inner wall 141 of theanchoring member 110) and the tubular member 148 (FIG. 21F). Theplurality of vertical septa 196 coupled between the anchoring member 110and the valve support 120 can be a flexible fabric or polymer, and insome embodiments, can be the same material used for the sleeve 146. Thesepta 196, which can be collapsed with the anchoring member 110 to a lowprofile delivery configuration (not shown) can also constrain theoutward deflection of the ribs 114 when the device 100 is in theexpanded configuration 102.

As described herein, the anchoring member 110 can be a structure orcomponent separate from the valve support 120. In one embodiment, theanchoring member 110 can be coupled to the valve support 120 at, forexample, a downstream end 123 of the valve support 120, while theupstream portion of the anchoring member 110 can remain uncoupled to thevalve support 120 and/or other otherwise be mechanically isolated fromthe valve support 120. The anchoring member 110 can be coupled to thevalve support 120 using a variety of mechanisms, including flexible, ornon-rigid, coupling mechanisms. FIGS. 22A-22G and 22I-22K are enlargedside views of various mechanisms of coupling the valve support 120 tothe anchoring member 110 that allow relative movement between thedownstream portions or the anchoring member 110 and the valve support120 or otherwise provide mechanical isolation of the valve support 120from the anchoring member 110 in accordance with additional embodimentsof the present technology.

FIGS. 22A-22B illustrate a downstream end 326 of a rib 114 of theanchoring member 110 coupled to a post 122 of the valve support 120. Ina first embodiment, the rib 114 can be coupled to the post 122 by asuture, wire or other suitable filament 310 which is wrapped around theadjacent elements and tied (FIG. 22B). In some embodiments, either orboth the rib 114 and the post 122 may have a feature to which thefilament 310 may be secured, such as a through-hole 312 (FIG. 22C), aloop or eyelet 314 (FIG. 22D), or a groove 316 configured to retain thefilament 310 therein and inhibit sliding along the rib 114 or post 122.

In another embodiment shown in FIG. 22F, the rib 114 can be coupled tothe post 122 by a rivet, screw, pin, or other fastener 318 which passesthrough aligned holes 319 in the rib 114 and the post 122.Alternatively, and as shown in FIGS. 220-22H, the post 122 may have acavity 320 in its outer wall configured to receive a downstream end 326of rib 144, and the two elements 114, 122 can be fastened together by afilament or fastener 322. In this arrangement, a substantial portion ofthe systolic force exerted on the valve support 110 can be translateddirectly to the rib 114 because the downstream end of the rib 114engages the floor of the cavity 320, thereby relieving the suture orfastener 322 from having to resist such force.

In further embodiments shown in FIGS. 22I-22J, a downstream end 326 ofthe rib 114 passes through a passage 324 formed through the post 122.The downstream end 326 is then secured to post 122 by a fastener 328 ora filament like those described above. Additionally, because the rib 114is held within the passage 324, the systolic loads exerted on the valvesupport 120 can be translated directly to the ribs 114 rather than tothe fastener 328. In yet another embodiment shown in FIG. 22K, adownstream end 330 of the post 122 is formed radially outward in a bookor J-shape, forming a channel 332 in which a downstream end 326 of therib 114 can be received. The ends 330, 326 of the two elements may besecured by a fastener 334 passing through holes 319 in the rib 114 andthe post 122. Systolic loads applied to the post 122 can be translateddirectly to the rib 114 via channel 332, relieving fastener 334 frombearing a substantial portion of the load.

FIGS. 23A-23B illustrate further embodiments of mechanisms suitable forcoupling the anchoring member 110 to the valve support 120. In theembodiments shown in FIGS. 23A-23B, circumferential connectors 116 ofthe anchoring member 110 are coupled to the struts 124 of the valvesupport 120. For example, in FIG. 23A, the connectors 116 are formed soas to have an hourglass-shaped portion 336 forming a waist 338 and anenlarged connector head 340 forming a connector cell 341. Struts 124similarly have an enlarged strut head 346 forming a strut cell 347. Thehourglass portion 336 of the connector 116 can be configured to passthrough the strut cell 347 such that the strut head 346 extends aroundthe waist 338 of the connector 116. The connector head 340 can besufficiently large that it is prevented from being released from thestrut call 347. Further, due to the diverging angles of connectorsegments 116A, 116B, the strut bead 346 can be prevented from slidingupward relative to the connector head 340. In such arrangements,systolic loads exerted in the upward direction on the valve support 120can be translated through the struts 124 to the connectors 116, which inturn translate these forces to the ribs 114 which are driven into thenative anatomy to anchor the device 100 in place.

In FIG. 238, the connectors 116 can be formed so as to have a loopportion 348 extending downwardly which is nested in a concave portion350 formed in the strut 124. The loop portion 348 can be fastened to theconcave portion 350 in various ways, e.g. by a suture 352 wrapped aroundeach member 348, 350. In this arrangement, systolic loads applied tovalve support 120 in the upstream direction can be transferred throughthe concave portion 350 to loop portions 348 of the anchoring member110.

In other embodiments, the anchoring member 110, or selected componentsthereof, can be integrally formed with the valve support 120. As shownin FIG. 24A, the ribs 114 of the anchoring member 110 can be integrallyformed with posts 122 of the valve support 120 with a U-shaped bridgemember 356 interconnecting each rib 114 to respectively aligned posts122. The ribs 114 may be circumferentially interconnected by expandableconnectors 116 formed integrally therewith. Alternatively, in theembodiment shown in FIG. 24A, a plurality of separate bands or wires 358extend around the circumference 150 of the anchoring member 110 and areeach slideably coupled to the ribs 114, e.g. by extending through a hole360 formed in each individual rib 114. The flexible bands or wires 358permit ribs 114 to be collapsed inwardly to a low-profile deliveryconfiguration (not shown), while limiting the outward deflection of theribs 114 when in the expanded configuration 102. Alternatively, a tether361 of wire or suture may be coupled between the individual ribs 114 andthe posts 122 (shown in FIG. 24B) to limit the outward deflection of theribs 114 when in the expanded configuration 102.

In further embodiments, a sleeve 146 may be secured to the ribs 114 in amanner which limits the outward deflection of the ribs 114 when thedevice 100 is in the expanded configuration (shown in FIG. 24C). Thesleeve 146 may, for example, extend around the outer side of each rib114 as shown in FIG. 24C to constrain it from expanding outwardly beyonda predetermined limit. Optionally, the sleeve 146 may further include ahorizontal septum 359 extending between an inner portion 146B of thesleeve 146 that extends around the valve support 120 and an outerportion 146A of the sleeve 146 that extends around the anchoring member110. The horizontal septum 359 can more rigidly constrain the outwardflexion of the ribs 114. In some embodiments, the septum 359 can alsoseal the annular cavity 163 formed by the septum 359 between the innerportion 146B and the outer portion 146A to limit blood flow into thiscavity 163 and minimizing clot formation therein. Alternatively,openings (not shown) may be formed in the sleeve 146 downstream of theseptum 359 which can permit blood to flow into the enclosed cavity 163to form a region of clot, thereby limiting the deflection of the ribs114 and making the device more rigid and securely anchored. The septum359, which can be a flexible fabric, polymeric, or pericardial material,can be located at the upstream end of the device 100 as shown, or at alocation spaced further downstream from the upstream end 121 of thevalve support 120. In a further embodiment shown in FIG. 24D, eachindividual rib 114 can be constrained within a passage 364 formed in thesleeve 146 by suturing or bonding two layers of sleeve fabric together.In the expanded configuration 102, the movement of the ribs 114 can belimited relative to the sleeve 146.

FIG. 25A is a partial cross-sectional view of a prosthetic heart valvedevice 100 having an anchoring member 110 and a valve support 120, andFIG. 25B is an enlarged view of the designated box shown in FIG. 25A inaccordance with an embodiment of the present technology. As shown inFIGS. 25A and 25B, there can be a gap 108 between the valve support 120and lower portion 111 of the anchoring member 110. If the gap 108exists, the gap 108 can be protected by a sleeve 146 to prevent bloodfrom leaking between the anchoring member 110 and the valve support 120in either an upstream or downstream direction.

FIGS. 26A-26D are schematic cross-sectional views of prosthetic heartvalve devices 100 having atrial retainers 410 and implanted at a nativemitral valve MV in accordance with various embodiments of the presenttechnology. FIGS. 26A-26C show several embodiments of the device 100 inwhich the device 100 includes an atrial retainer 410 configured toengage a supra-annular surface of the annulus AN or other tissue withinthe left atrium to assist the native leaflets in preventing downstreammigration of the device 100 into the left ventricle. In thesearrangements, the annulus AN can be sandwiched between a topcircumference 150 of the anchoring member 110 and a bottom surface ofthe atrial retainer 410.

As shown in FIG. 26A, one embodiment of the device 100 can include theatrial retainer 410 coupled to or integrally formed with the inner valvesupport 120. The atrial retainer 410 can extend upstream through theannulus AN and into a supra-annular space within the atrium and engagethe supra-annular surface or other atrial tissue with an outwardlyextending flange 420. In another embodiment shown in FIG. 268, theatrial retainer 410 can comprise a plurality of fingers 412 which may beformed integrally with or otherwise coupled to the valve support 120(e.g. comprising upward extensions of posts 122 or upward extensions ofthe anchoring member 110). The fingers 212 can be generally uncovered orexposed within the left atrium as illustrated in FIG. 26B; however, inanother embodiment, the fingers 412 can be covered with a sealing member(not shown) or other covering of fabric, polymeric sheet, or pericardialtissue extending around the outside or inside surfaces of the fingers412 to form a conical shape to help seal the device 100 with the nativetissue on the atrial side of the annulus AN and to help funnel bloodinto the prosthetic valve 130 (FIG. 10A). The fingers 412 may alsoinclude circumferential struts (not shown) interconnecting the fingers412 to limit lateral deflection and enhance the stiffness of thefingers. The fingers 412 can include a resilient shape memory material(e.g., Nitinol) such that the fingers can be straightened and deflectedinwardly for delivery and be released to an unbiased, radiallyprojecting outward position in the expanded configuration 102 as shown.For example, the fingers 412 can have finger tips 414 biased outwardlyand, in some arrangements, in the downstream direction in the expandedconfiguration 102. During delivery to a desired position within thenative mitral valve MV, the device 100 can be unsheathed in the distalor downstream direction (discussed in more detail below), such that thefingers 412 are first released to engage the atrial side of the valveannulus AN. This indexes the position of the device 100 relative to thenative valve to ensure that the anchoring member 110 is positioned onthe ventricular side of the native annulus AN but not overextended intothe ventricle when it is unsheathed and expanded.

The atrial retainer 410 may alternatively be an extension of theanchoring member 110. In one embodiment shown in FIG. 26C, the atrialretainer 410 can include a plurality of atrial loops 416, which,although depicted in a more vertical plane, may alternatively lie in aplane more parallel to the plane of the native annulus AN, and whichextend upstream through the annulus AN, then extend radially outwardlyto engage a supra-annular surface. The loops 416, which may compriseextensions of one or more ribs 114 of the anchoring member 110, caninclude a resilient shape-memory metal (e.g., Nitinol) or other materialthat may be compressed into a low profile shape for delivery thenreleased to expand to the radially-extended configuration shown in FIG.26C. Similar to the device 100 of FIG. 26C, FIG. 26D is also across-sectional view of a prosthetic heart valve device 100 thatincludes an atrial retainer 410 formed by an extension of the anchoringmember 110. As shown in FIG. 26D, the atrial retainer 410 can include acylindrical portion 418 which extends upwardly from the anchoring member110 through the native annulus AN, with a flange 420 at the proximalregion which extends over the atrial aide of the native annulus AN toengage the supra-annular surface. The flange 420 can include a resilientshape memory material (e.g., Nitinol) that can be collapsed for deliveryand expand when deployed at the native mitral valve MV. The cylindricalportion 418 and flange 420 may be integrally formed with the anchoringmember 110, e.g. comprised of extensions of the ribs 114, or in anotherembodiment, can be coupled to one or more portions of the anchoringmember 110 and/or the valve support 120.

In other embodiments, the prosthetic heart valve device 100 can includeatrial extending features that assist in retaining the device 100 in adesired location within the native mitral valve, but do notsubstantially engage atrial or supra-annular tissue. For example, FIG.27 is a side view of an anchoring member 110 having a vertical portion422 at the upstream end 424 for engaging the annulus AN in accordancewith another embodiment of the present technology. The anchoring member110 can include the lower portion 111 and the upper flared portion 112which is positionable in a subannular location between the leaflets LFand downstream of the annulus AN. The upstream portion 112 can beexpandable to a dimension that is larger than a corresponding dimensionof the subannular tissue and/or inward facing leaflets LF. The verticalportion 422 can be fitted within the annulus orifice so as to engage theannulus AN around an entire upstream circumference 150 of the anchoringmember 110. The vertical portion 422 can be expandable to a dimensionthat is larger than a corresponding dimension of the annulus AN suchthat radial expansion of the vertical portion 422 presses outwardlyagainst the native tissue to assist retaining the device in the desiredlocation with the native mitral valve. Optionally, the anchoring member110 can also include a plurality of tissue engaging elements 170, suchas spikes. In one embodiment, the spikes (shown here as tissue engagingelements 170) can be distributed around the circumference 150 of theupper portion 112 of the anchoring member 110 and oriented such that thespikes can penetrate tissue in a subannular location and can beconfigured to help the anchoring member 110 resist movement in either anupstream or downstream direction.

Prosthetic Heart Valve Devices Having Stabilizing Members

FIG. 28 illustrates one embodiment of the prosthetic heart valve device100 in an expanded configuration 102 that further comprises one or morestabilizing members 501 to help stabilize the device 100 at the nativevalve site and, in some embodiments, prevent tilting or lateralmigration, or to inhibit upstream or downstream migration of the device100. In some embodiments, the stabilizing members 501 may comprise oneor more arms 510 extending from a lower or downstream portion 111 of theanchoring member 110. The arms 510 are configured to engage the nativetissue, e.g. the valve leaflets, subannular tissue, or ventricular wall,either inside or outside the native leaflets, depending on theconfiguration.

FIG. 29 is an enlarged schematic, side view of a prosthetic heart valvedevice having an extended arm in accordance with an embodiment of thepresent technology. As shown in FIG. 29, an individual arm 510 maycomprise an arm body 512, an arm extension 514, and an arm tip 516. Thearm body 512 has an arm body length L₁ and may connect to a post 511 ata first joint 508. The post 511 can be a valve support post 122, ananchoring member rib 114, and/or another feature of the device 100(e.g., strut 124 or connector 116). A first arm angle A_(A1) is formedby the intersection of the axes of post 511 and the arm body 512; thefirst arm angle A_(A1) selected such that the arm 512 is positionable sothat the tip 516 can engage the native tissue at a desired location,e.g. the subannular tissue or ventricular wall behind the nativeleaflets. FIGS. 30A-30C are enlarged partial side views of a prostheticheart valve device 100 having arms 510 coupled to the device at variousangles with respect to a longitudinal axis 101 of the device inaccordance with further embodiments of the present technology. In oneembodiment, the first arm angle A_(A1) can be about 10° to about 45°. Inother embodiments, the first arm angle A_(A1) can be an obtuse angle(FIG. 30A), generally perpendicular or approximately a 90° angle (FIG.30B), or an acute angle (FIG. 30C).

Referring back to FIG. 29, the arm body 512 can connect to the armextension 514 at a distal end of the arm body 512. The arm extension 514can have an arm extension length L₂ which can be selected or optimizedfor penetrating a desired distance into the native tissue, such as about0.5-2 mm. The arm extension 514 can extend from the arm body 212 atsecond arm angle A_(A2). The second arm angle A_(A2) can be formed bythe intersection between the arm extension 514 and arm body 512 and beselected to provide the desired angle of engagement with the nativetissue, such as about 100° to about 135°. In other embodiments, the armextension 514 may be parallel or collinear with the arm body 512 (notshown), or may be eliminated entirely. The arm extension 514 terminatesat the arm tip 516. In embodiments without an arm extension 514, the armtip 516 can be the most distal portion of the arm body 512 (not shown).

The arm 510 may have an arm height H_(A1) extending from the first joint508 to the most distal reaching point of the arm, which could be the armtip 516 (shown in FIG. 29) along an axis parallel to the longitudinalaxis 101 of the device 100. The arm height H_(A1) can be selected oroptimized such that the arm tip 516 engages a desired location in thesubannular anatomy when the device 100 is in a desired longitudinalposition relative to the native mitral valve (e.g., when the anchoringmember 110 is in engagement with the subannular tissue). The arm heightH_(A1) will depend upon of the overall height of the anchoring member110 and/or valve support 120 as well as the location of the joint 508.FIGS. 31A-31C are enlarged, partial side views of prosthetic heart valvedevices having arms 510 of various lengths (L₁+L₂), and accordinglyhaving variable heights H_(A1). As shown, the arm height H_(A1) may begreater than the overall height H_(D1) of the anchoring member 110(represented by rib 114) or valve support (FIG. 31A), be intermediatebetween the respective heights H_(D1), H_(V1) of the anchoring member110 (represented by rib 114) and the valve support 120 (represented bypost 122) (FIG. 31B), or be less than the overall height H_(D1) of boththe anchoring member 110 (represented by rib 114) and the valve support120 (FIG. 31C).

Additional details and embodiments regarding the structure andattachment of arms or other stabilizing members suitable for use withthe device 100 can be found in International PCT Patent Application No.PCT/US2012/043636, entitled “PROSTHETIC HEART VALVE DEVICES ANDASSOCIATED SYSTEMS AND METHODS,” filed Jun. 21, 2012, the entirecontents of which are incorporated herein by reference.

FIGS. 32A, 32B, 32C, and 32D are cross-sectional views of a heart withan implanted prosthetic heart valve device 100 having arms 510 adisposed on an inward-facing surface of the leaflets LF, and FIGS.32A-1, 32B-1, 32C- and 32D-1 are enlarged views of the arms 510 aengaging the inward-facing surface of the leaflets as shown in FIGS.32A, 32B, 32C and 32D, respectively. The embodiments of prosthetic heartvalve devices 100 illustrated in FIGS. 32A-32D-1 have arms 510 aconfigured to expand to a position radially inside the leaflets LF,radially outside the leaflets LF, or a combination of inside and outsidethe leaflets LF. For example, FIGS. 32A and 32A-1, show arms 510 aexpanding and engaging an inward surface of the leaflets LF and show thearms 510 a partially piercing the leaflets LF. In another exampleillustrated in FIGS. 32B and 32B-1, the arms 510 a may fully penetratethe leaflets LF. In a further example, the device 100 can incorporatearms 510 a that 1) completely penetrate the leaflets LF and 2) partiallypierce subannular tissue (FIGS. 32C and 32C-1). Referring to FIGS. 32Dand 32D-1, the device 100 can be configured to incorporate arms 510 athat fully penetrate both the leaflets LF and the annular tissue of themitral valve MV.

FIGS. 33A-33C are schematic views illustrating various embodiments oftissue engaging elements 170 for use with prosthetic heat valve devices100 in accordance with the present technology. Tissue engaging elements170 can include any feature that engaged tissue in an atraumatic manner,such as a blunt element, or which partially pierces or fully penetratescardiac tissue, such as a barb or spike. As used herein, “tissueengaging” refers to an element 170 which exerts a force on the tissue Tbut does not necessarily pierce the tissue T, such as being atraumaticto the tissue T, as shown in FIG. 33A. As used herein, “partiallypiercing” refers to a tissue engaging feature 170 which at leastpartially penetrates the tissue T but does not break through an oppositesurface S, as shown in FIG. 33B. As used herein, “fully piercing” refersto a tissue engaging feature 170 which can both enter and exit thetissue T, as shown in FIG. 33C. “Piercing” alone may refer to eitherpartial or full piercing. Tissue engaging elements 170 may take the formof spikes, barbs, or any structure known in art capable of piercingcardiac tissue, or alternatively, any blunt or atraumatic featureconfigured to apply pressure on the cardiac tissue without piercing thetissue. Further details on positioning of such elements is describedherein.

FIGS. 34A, 34B and 34C are cross-sectional views of a heart with animplanted prosthetic heart valve device 100 having arms 510 a withtissue engaging elements 170 disposed on an inward-facing surface of theleaflets LF, and FIGS. 34A-1, 34B-1 and 34C-1 are enlarged views of thearms 510 a engaging the inward-facing surface of the leaflets LF asshown in FIGS. 34A, 34B and 34C, respectively. As illustrated in FIGS.34A-34C-1, tissue engaging elements 170 can be incorporated on andextend from the arms 510 a in either a downstream direction (FIGS. 34Aand 34A-1), upstream direction (FIGS. 34B and 34B-1), or in both thedownstream and upstream directions (FIGS. 34C and 34C-1). In otherembodiments, the tissue engaging elements 170 can be incorporated on andextend from the components of the anchoring member 110 and/or the valvesupport 120 in either or both the upstream and downstream directions.

FIGS. 35A-35C are side views showing prosthetic heart valve devices 100implanted at a mitral valve MV (illustrated in cross-section) in adeployed configuration 104, wherein the devices have arms 510 b forengaging an outward-facing surface of the native leaflets LF inaccordance with various embodiments of the present technology. FIG. 35Ashows an embodiment of the device 100 that includes arms 510 bconfigured to extend from the downstream end of the device 100 (e.g.,the ventricular end of a device implanted at a native mitral valvedownstream of the leaflets) to reach behind the leaflets LF such thatthe leaflets LF are effectively sandwiched between the arms 510 b andthe outer wall 142 of the anchoring member 110. In another embodiment,and as shown in FIG. 35B, the arms 510 b may cause leaflets LF to foldupon themselves in the space between the arms 510 b and the outer wall142 of the anchoring member 110. In a further embodiment illustrated inFIG. 35C, the arms 510 b can also include the tissue engaging elements170. FIG. 35C-1 is an enlarged view of the arm 510 b having tissueengaging elements 170 for engaging the outward-facing surface of theleaflets LF as shown in FIG. 35C. As shown in FIG. 35C-1, the arms 510 bconfigured to engage an outside-facing surface of the native leaflets LFmay include tissue engaging elements 170 on an inside surface of thearms 150 b such that they are oriented toward the leaflet tissue.

In accordance with another embodiment of the present technology, FIG.36A is a side view showing a prosthetic heart valve device 100 implantedat a mitral valve MV (illustrated in cross-section). The device shown inFIG. 36A has arms 510 b for engaging an outward-facing surface of thenative leaflets LF and arms 510 a for engaging an inward-facing surfaceof the native leaflets LF. Inside/outside arms 510 a, 510 b may furthercomprise tissue engaging elements 170 on a radially inside surface orradially outside surface of the arms 510 a, 510 b, respectively, forengaging or piercing the leaflet tissue. The arrangement ofinside/outside arms 510 a, 510 b around a circumference of the device100 can alternate in a pre-designed pattern. For example, inside arms510 a can alternate with outside arms 510 b as shown in FIG. 36B, oralternatively, arms 510 a, 510 b may extend radially outward and/orradially inward randomly or at irregular intervals, depending onplacement of the device 100 and with respect to alignment with thenative posterior and anterior leaflets.

FIGS. 37A-37D are enlarged side views of additional embodiments of arms510 suitable for use with a prosthetic heart valve device 100 inaccordance with the present technology. For example, in FIGS. 37A-37D,the arms 510 can have a similar overall profile as a profile of theanchoring member 110. The anchoring member 110 can include ribs havingvarying shapes, sizes and/or outwardly or inwardly oriented rib segments85 for forming the overall anchoring member profile. Accordingly, theanus 510 can also have varying shapes, sizes and/or outwardly orinwardly oriented arm segments that mimic the anchoring member 110profile. In some arrangements, the embodiments shown in FIGS. 37A-37Dare configured to clamp leaflets LF and/or the annulus AN tissue betweenthe arms 510 and the ribs 114 so as to conform the leaflet tissue to theshape of the anchoring device 110 for enhanced sealing and anchoring ofthe device. For example, FIG. 37A illustrates one embodiment in whicharm extensions 514 and/or arm bodies 512 may partially mimic the shapeof the ribs 114 and/or rib segments 85, and FIG. 37B illustrates anotherembodiment in which arm extensions 514 and/or arm bodies 512 moreclosely follow the shape of the ribs 114. Embodiments encompassed byFIGS. 37A-37B can apply to outward surface engaging arms 510 b and/orinward surface engaging arms 510 a. Additionally, as shown in FIGS.37A-378, the arm extensions 514 can extend radially outwardly so as tobe generally parallel with an upstream segment 85A of the rib 114. Thearm extension 514 can be configured to extend partially along the lengthof the rib 114 and/or rib segments 85 (FIGS. 37A and 37C) or fully alongthe length of the rib 114 and/or rib segments 85. In FIG. 37D, the arms510 have second arm extensions 518 connected to an upstream portion ofthe first arm extension 514 and extending outwardly so as to begenerally parallel to a second rib segment 85B and third rib segment85A.

In some embodiments, the prosthetic heart valve device 100 mayincorporate a plurality of arms 510 around a circumference of the device100; however, in other embodiments, the device may include the pluralityof arms in groupings (e.g., first and second groupings so as to engagethe posterior and anterior leaflets, respectively). Additionally, thearms 510 may extend from the anchoring member 110 and/or valve support120 independently of other components including other arms 510, such asshown in FIG. 38A. In other embodiments and as shown in FIG. 38B, thedevice 100 may further include at least one first arm 510 xinterconnected with at least one second arm 510 y by interconnecting armstruts 520. The arm struts 520 can be configured to be circumferentiallyexpandable and may connect all arms 510 (e.g., arm 510 x and 510 y) orone or more groups of arms 510. In some embodiments, the arm struts 520can limit the outward extension of the arms 510 x, 510 y away from thedevice 100.

In accordance with aspects of the present technology, the arms 510 canbe coupled to and/or extend from components of the device 100symmetrically and/or asymmetrically around the circumference 150 of thedevice 100. FIGS. 39A-39D are schematic top views of arm locationpatterns with respect to the ribs 114 of the anchoring member 110 (e.g.,as shown in FIG. 38A). The arms 510 can be interspersed with ribs 114(FIGS. 39A and 39C), in the same radial plane as the ribs 114 of theanchoring member 110 (FIG. 39B), or both interspersed and in plane withthe ribs 114 (FIG. 39D). Further, the arms 510 may be configured toextend outside the expanded outer circumference 150 of the anchoringmember 110 (FIG. 39B), inside the expanded outer circumference 150 ofthe anchoring member 110 (FIG. 39A), extend to the same outercircumference 150 of the anchoring member 110 (FIG. 39C), or acombination of these configurations (FIG. 39D).

In the above-described embodiments, the arms 510 may be configured toengage tissue independently of the deployment of anchoring member 110.For example, delivery catheters suitable for the delivery of theprosthetic heart valve devices 100 may be equipped with separatemechanisms operable to deploy the arms 510 and the anchoring members 110individually or otherwise independently of each other. In this way, theanchoring member 110 may be first released into engagement with thenative tissue so that the position of device 100 may be assessed andadjusted by the operator until the desired final position has beenattained. Following deployment and positioning of the anchoring member110, the arms 510 can be released to engage the tissue. Such deploymentsystems and methods are useful when the arms 510 are equipped withtissue engaging elements 170 which, once deployed, may prohibit anyrepositioning of the device 100. In some embodiments, the anchoringmember 110 will be equipped with atraumatic tissue engagement elements170 which do not penetrate tissue or inhibit device relocation once theanchoring member 110 has been deployed. Accordingly, some embodiments ofthe device 100 may be repositionable even with the anchoring member 110expanded so long as the arms 510 are constrained in an undeployedconfiguration, with the device 100 becoming permanently anchored onlywhen the arms 510 are released.

Alternatively or in addition to tissue engaging elements 170 present onthe arms 510 as described above, tissue engaging elements 170 may bepresent on other components of the device 100. FIGS. 40A-40E are sideviews of prosthetic heart valve devices 100 having tissue engagingelements 170 on varying structures of the device 100 in accordance withadditional embodiments of the present technology. For example, tissueengaging elements 170 can be incorporated on the ribs 114 of theanchoring member 110. FIG. 40A shows tissue engaging elements 170incorporated on the upper rib segment 85A, and FIG. 40B shows the tissueengaging elements 170 incorporated on lower rib segment 85B. FIG. 40Cillustrates an embodiment of the device having the tissue engagingelements 170 along the entire rib 114. The tissue engaging elements 170are shown in FIGS. 40A-40C schematically, but one of ordinary skill inthe art will recognize that the elements can be any of a variety oftissue engaging elements 170 described herein (e.g., atraumatic,partially piercing, fully penetrating, etc.), or in other embodiments, acombination of different types of tissue engaging elements 170.Additionally, the tissue engaging elements 170 are shown oriented in anupstream direction (e.g., to inhibit upstream migration of the device100); however, in other embodiments, the tissue engaging elements 170can be oriented in a downstream direction (e.g., to inhibit downstreammigration of the device 100), or in a combination of downstream andupstream oriented directions. The tissue engaging elements 170 can beincorporated symmetrically around a circumference of the device 100, orin other embodiments, the tissue engaging elements 170 can beincorporated asymmetrically. For example, in some embodiments, thetissue engaging elements 170 can be present on a side of the device 100aligned with the posterior leaflet, but be absent or have a differentarrangement on a side of the device 100 aligned with the anteriorleaflet such that the wall separating the aortic valve from the leftventricle will not be affected by the tissue engaging elements 170.

FIG. 40D illustrates an embodiment of the device 100 having tissueengaging elements 170, such as spikes on an upstream tip 175 of the rib114, wherein the spikes can be configured to fully or partiallypenetrate subannular tissue when the device 100 is deployed on or underthe annulus of the mitral valve. In some embodiments, the tissueengaging elements 170 (e.g., spikes) can include barbs 176 or otherfeatures for retaining the tissue engaging elements 170 (e.g., spikes)in the tissue. In other embodiments, the tissue engaging elements 170(e.g., spikes) can be blunt so as to engage but not penetrate thesubannular tissue. FIGS. 40E-40G are enlarged side views of tissueengaging elements 170 (e.g., spikes) suitable for use on upstream tips175 of the ribs 114. Devices 100 having tissue engaging elements 170 onthe upstream tips 175 can also incorporate features for limiting thedistance of penetration into the tissue. For example, the upstream tip175 can have a hilt 177 formed a short distance, e.g. 1-5 mm, proximalto the tip of each tissue engaging element 170 to limit the distance towhich the tissue engaging element 170 can penetrate the subannulartissue (FIG. 40E). Alternatively, as shown in FIG. 40F, the depthpenetration of the tissue engaging element 170 into the tissue can belimited by positioning connectors 116 a desired distance from the tipsof the tissue engaging element 170. In a further embodiment shown inFIG. 40G, a sealing member 140 may be attached to the ribs 114 such thatthe upstream edge 178 of the sealing member 140 can limit the depth ofpenetration of the tissue engaging element 170. In order to preventslippage of the sealing member 140 downward, an attachment feature suchas a hole 173 configured to receive a suture may be formed in the rib114 at the desired distance from its upstream tip 175 to which thesealing member 140 can be firmly secured.

Alternatively, tissue engaging elements 170, such as bumps, ridges, orother protrusions configured to exert frictional forces on cardiactissue, may be also present on one or more valve support struts 124,valve support posts 122, and/or other components (e.g., sealing members140). These tissue engaging elements 170 can be disposed on an outerportion of these features and can be configured to extend outwardly toengage the native leaflets and to stabilize and firmly anchor the device100 in the desired location. Alternatively, ridges, scales, bristles, orother features having directionality may be formed on the surface of theribs 114, connectors 116, or sealing member 140 to allow movementrelative to native tissue in one direction, while limiting movement inthe opposite direction.

The tissue engaging elements 170 on the anchoring member 110 can bebarbs, spikes, or other retention features configured to have a delayeddeployment so as to allow the device to be repositioned or removed for aperiod of time until these elements become fully deployed. For example,the tissue engaging element 170 may be constructed of a shape memorymaterial (e.g., Nitinol) which is preshaped in a deployed configurationand adapted to retain the tissue engaging element 170 in the nativetissue. The tissue engaging element 170 may be deformed into acontracted configuration which permits removal from tissue, and retainedin this shape by a bioerodable material or adhesive. Once immersed intissue, this material can erode over a period of time (e.g., 10minutes-2 hours) allowing the tissue engaging element 170 to return toits unbiased deployed shape which will assist in retaining the tissueengaging element 170 in the tissue.

Several examples of such delayed, deployable tissue engaging elements170 are shown in FIGS. 40I-40T. In the embodiment of FIG. 40I, thetissue engaging element 170 comprises a shape memory alloy shaft 450laser cut so as to have a diamond-shaped window 451 near its distal tip452, which can be sharp enough to penetrate tissue. The shape set sothat window 451 is biased toward being open in an expanded configurationas shown in FIG. 40I. Prior to delivery of the device, window 451 may bepinched closed and a bioerodable glue 455 may be injected into window451 to hold it in a closed configuration as shown in FIG. 40J. Upondeployment of the device, the distal tip 452 can penetrate the nativetissue, e.g. valve leaflet or annulus, as shown in FIG. 40K. The glue455 within window 451 maintains it in a closed configuration for aperiod of time to allow the operator to reposition or remove the deviceif necessary. If left in position, the glue 455 erodes, allowing thewindow 451 to reopen into the expanded configuration which will retainthe tissue engaging element 170 in the tissue as shown in FIG. 40L.

In the embodiment shown in FIGS. 40M-40P, the tissue engaging element170 comprises an arrowhead-shaped tip 453 having two or more wings 454biased to be angled radially outward and pointing in a proximaldirection as shown in FIG. 40M. A bioerodable glue or coating 455 isapplied over the arrowhead tip 453 to hold the wings 454 in a radiallycontracted configuration as shown in FIG. 40N. In the contractedconfiguration, the device 100 is deployed such that the tissue engagingelement 170 pierces the native tissue as shown in FIG. 40O. Thebioerodable coating 455 then erodes gradually until it allows the wings454 to return to the laterally expanded configuration shown in FIG. 40P,thus retaining the tissue engaging element 170 in the tissue.

A further embodiment is shown in FIGS. 40Q-40T. In this embodiment, thetissue engaging element 170 comprises a helical tip 456 in an unbiasedstate. A bioerodable coating 455 may be used to retain the helical tip456 in a straightened configuration as shown in FIG. 40R. The tissueengaging element 170 can penetrate the tissue in the contractedconfiguration, and when the bioerodable coating 455 erodes sufficientlyto allow the helical tip 456 to return to its deployed configuration,the tissue engaging element 170 can be retained in the tissue.

The prosthetic heart valve device 100 can also be configured to haveadditional tissue engaging elements 170 for engaging the annulus. Forexample, FIG. 41 is an isometric view of a prosthetic heart valve device100 having a plurality of annulus engaging elements 179 in accordancewith a further embodiment of the present technology. The annulusengaging elements 179 can be a C-shaped hook feature or other shape thatallows the element 179 to engage tissue on the annulus, as well as aportion of supra-annular tissue and subannular tissue. As shown, theannulus engaging elements 179 can be symmetrically (shown in FIG. 41) orasymmetrically interspersed around the upstream perimeter of theanchoring member 110 and coupled to ribs 114, connectors 116 (notshown), or to a sealing member 140. The annulus engaging elements 179may also be coupled to the anchoring member 110 at other locationsdownstream of the upstream perimeter 113, or in other embodiments to aportion of the valve support 120 that extends through at least theannulus plane PO (FIG. 3). Additionally, the annulus engaging elements179 may be blunt (e.g., for pressing but not penetrating into theannular tissue), or they may be sharp for penetrating the annulus tissueon either or both of the supra-annular or subannular surfaces. Theannulus engaging element 179 can be suitable for both positioning thedevice 100 in the desired location (e.g., with anchoring member 110below the annulus), as well as to inhibit movement of the device ineither an upstream or downstream direction.

In another embodiment shown in FIGS. 42A-42B, a prosthetic heart valvedevice 100 can have tissue engaging elements 372 deployable from aplurality of tubular ribs 314. Referring to FIG. 42A, the prostheticheart valve device 100 can have an anchoring member 110 having aplurality of tubular ribs 314 configured to retain a plurality ofdeployable tissue engaging elements 372. FIG. 42B is an enlarged view ofthe tubular rib 314 and a deployable tissue engaging element 372retained within a lumen 316 of the rib 314 and shown before deploymentof the element 372. The tissue engaging element 372 can comprise a shapememory material (e.g., Nitinol) configured to deploy to a preformedshape upon release of the tissue engaging element 372 from the innerlumen 316 of the rib 314. Release of the tissue engaging element 372 canbe achieved by engaging a proximal end 374 of the tissue engagingelement 372. For example, the proximal end 374 can be engaged during thedeployment of the device 100 to release the tissue engaging element 372after the anchoring member 110 is positioned at the desired locationbelow the annulus AN. The tubular rib 314 can include a U-shapeddeflector 318 and a pivot point 320 configured to guide the tissueengaging element 372 distally through a distal opening 315 of the rib314. As illustrated in dotted lines in FIG. 42B, engagement of theproximal end 374 of element 372 will encourage a distal end 376 of thetissue engaging element 372 from the distal opening 315 of the tubularrib 314 to penetrate adjacent subannular tissue. Once deployed and afterexiting an opposing surface S, such as the supra-annular surface, thetissue engaging element 372 can transition into its preformed shape,such as a curled shape 378 that can resist retraction of the distal end376 from the tissue.

In accordance with another embodiment of the prosthetic treatment device100, tissue engaging elements 170 can be incorporated into sealingmembers 140 (e.g., sleeve 146). FIGS. 43A-43B are an isometric view andan enlarged detail view of a prosthetic heart valve device 100 having asealing member 140 configured with tissue engaging elements 170.Referring to FIGS. 43A-43B together, the tissue engaging elements 170can comprise metallic or polymeric wires 274 or fibers, rigid and sharpenough to penetrate tissue, which are woven into or otherwise coupled tosealing member 140 materials. The sealing member 140 can then beattached to outer and/or inner walls 141, 142 of the anchoring member110 and/or interior and/or exterior surfaces 126, 127 of the valvesupport 120 such that tissue engaging elements 170 extend radiallyoutward from the sealing member 140 to engage the adjacent leaflets orother tissue.

FIGS. 44A-44F are enlarged side views of embodiments of additionaltissue engaging elements that can be incorporated on various devicestructures (referred collectively as “ST”), such struts, connectors,posts, arms, and/or ribs which may be incorporated into device features,such as the anchoring member 110 or valve support 120. For example, theadditional tissue engaging elements may comprise one or more cut-outprotrusions 350 (FIGS. 44A and 44B) in place of or in addition to tissueengaging elements 170. In a collapsed or straightened configuration, asshown by the side view of FIG. 44C, cut-out protrusion 350 maintains lowrelief relative to the surface of structure ST to maintain a low profileduring delivery. As the device 100 expands and structure ST changes toits deployed configuration (e.g. a curvature as shown m FIG. 44D), theprotrusion separates from the ST to a higher relief. The protrusion 350may also be configured to grab subannular tissue pulling the cut-outprotrusions even farther away from structure ST. The device structuresST may also be shaped to include sharp protrusions 352 along one or moreof its edges or faces, as illustrated in FIG. 44E, or may also includepointed scale-like protrusions 354, as shown in FIG. 44F.

In addition to the stabilizing members 501 described above, theprosthetic heart valve devices described herein (e.g., devices 100) mayalso include support features such as tethers 360 and sealing membersepta 370 for stabilizing the anchoring member 110 and/or the valvesupport 120, and/or for spreading pressure gradient loads evenly over agreater area of the device 100 (e.g., during ventricular systole).Referring to FIG. 45A, one example of the device 100 can incorporate aplurality of tethers 360 at least loosely coupling the upper portion 112of the anchoring member 110 to the upstream end 121 of the valve support120. In one embodiment, the tethers 360 can include a single suture thatis run continuously around the circumference 150 of the anchoring member110. In another embodiment, the device 100 can include several suturesof discreet lengths tied between the anchoring member 110 and the valvesupport 120. In one embodiment the tethers can be a suture comprisingpolytetrafluoroethylene (PTFE). Generally, the tethers 360 assist indistributing forces evenly along the anchoring member 110 withoutdeforming the valve support 120 or compromising the closure of theprosthetic valve 130. In some arrangements, the tethers 360 can assistin limiting radial expansion of the upstream portion. Accordingly, evenwith the incorporation of the tethers 360, the valve support 120 remainsmechanically isolated from at least the upstream portion of theanchoring member 110.

FIG. 45B shows another example of a stabilizing member 501 suitable tostabilize the anchoring member 110 and/or the valve support 120, and/orfor spreading pressure gradient loads evenly over a greater area of thedevice 100 (e.g., during ventricular systole). As shown in FIG. 45B, thedevice 100 can include a plurality of sealing member septa 370 extendingbetween the anchoring member 110 and the valve support 120. In theillustrated embodiment, the septa 370 can be extensions of the sealingmember material configured to span between a sealing member 140, such asa skirt 144, coupled to the inner wall 141 of the anchoring member 110and a sealing member 140, such as a sleeve 146, coupled to an interioror exterior surface 126, 127 of the valve support 120. Accordingly, thesepta 370 can be formed of fabric or other flexible and biocompatiblematerials such as Dacron®, ePTFE, bovine pericardium, or other suitablematerials. Similar to the embodiment illustrated in FIG. 45A, the septa370 can assist in distributing forces evenly along the anchoring member110 without deforming the valve support 120 or otherwise compromisingthe closure of the prosthetic valve 130. In some arrangements, the septa370 can assist in preventing the device 100 from everting duringventricular systole. Accordingly, even with the incorporation of thesepta 370, the valve support 120 is mechanically isolated from at leastthe upstream portion of the anchoring member 110.

Each of the elements and members of the device 100 may be made from anynumber of suitable biocompatible materials, e.g., stainless steel,nickel titanium alloys such as Nitinol™, cobalt chromium alloys such asMP35N, other alloys such as ELGILOY® (Elgin, Ill.), various polymers,pyrolytic carbon, silicone, polytetrafluoroethylene (PTFE), or anynumber of other materials or combination of materials depending upon thedesired results. The arm members 510, sealing member 140, sleeves 146,anchoring member 110 and/or valve support 120 or other elements ofdevice 100 may also be coated or covered with a material that promotestissue in-growth (e.g., Dacron®, PTFE, etc.)

Delivery Systems

FIGS. 46A-46D illustrate one embodiment of a delivery system 10 suitablefor delivery of the prosthetic heart valve devices disclosed herein. Asused in reference to the delivery system, “distal” refers to a positionhaving a distance farther from a handle of the delivery system 10 alongthe longitudinal axis of the system 10, and “proximal” refers to aposition having a distance closer to the handle of the delivery system10 along the longitudinal axis of the system 10.

FIG. 46A illustrates one embodiment of the delivery system 10 which maybe used to deliver and deploy the embodiments of the prosthetic heartvalve device 100 disclosed herein through the vasculature and to theheart of a patient. The delivery system 10 may optionally include aguiding catheter GC having a handle 12 coupled to a delivery shaft 16,which in one embodiment is 34 F or less, and in another embodiment, 28 For less in diameter. The guiding catheter GC may be steerable orpreshaped in a configuration suitable for the particular approach to thetarget valve. The delivery catheter 18 is placed through a hemostasisvalve HV on the proximal end of guiding catheter GC and includes aflexible tubular outer shaft 19 extending to a delivery sheath 20 inwhich the device 100 is positioned in a collapsed or deliveryconfiguration 106. A flexible inner shaft 28 is positioned slideablywithin outer shaft 19 and extends through the device 100 to a nosecone21 at the distal end. The inner shaft 28 has a guidewire lumen throughwhich a guidewire 24 may be slideably positioned. The device 100 iscoupled to the inner shaft 28 and is releasable from the inner shaft 28by release wires 30, as more fully described below. The delivery sheath20 can protect and secure the device 100 in its collapsed configuration106 during delivery. The outer shaft 20 is coupled to a retractionmechanism 23 on the handle 14 of the delivery catheter 18. Variousretraction mechanisms 23 may be used, such as an axially-slidable lever,a rotatable rack and pinion gear, or other known mechanisms. In thisway, the outer shaft 20 may be retracted relative to the inner shaft 28to release (e.g., deploy) the device 100 from the sheath 20.

FIG. 46B shows the distal end of the delivery catheter 18 with thesheath 20 cut away to illustrate the coupling of the device 100 to theinner shaft 28. A plurality of locking fingers 32 are coupled to thenose cone 21 and extend proximally through the interior of the valvesupport 120 of the device 100. As shown in FIG. 46C, a selected numberof posts 122 of the valve support 120 have a coupling element 61comprising a tab 34 cut out from each post 122 at a proximal endthereof. The tab 34 may be deflected inwardly from the post 122 as shownin FIG. 46B and is configured to extend through a window 42 in thelocking finger 32 as shown in FIG. 46D. The release wires 30 passthrough the holes 40 in the tabs 34, which prevents the tabs 34 frombeing withdrawn from the windows 42 to secure the device 100 to theinner shaft 28. The pull-wires 30 can be sandwiched tightly between thetabs 34 and the locking fingers 32, such that friction temporarilyprevents the pull-wire 30 from slipping in a proximal or distaldirection. In this way, the sheath 20 may be retracted relative to thedevice 100 to permit expansion of the device 100 while the inner shaft28 maintains the longitudinal position of the device 100 relative to theanatomy. The pull-wires 30 may extend proximally to the handle 14, forexample, in between the inner shaft 28 and the outer shaft 19 or withinone or more designated lumens. A suitable mechanism (not shown) on thehandle 14 can allow the operator to retract the release wires 30 in aproximal direction until they are disengaged from the tabs 34.Accordingly, the device 100 can be released from the locking fingers 32and expand for deployment at the target site.

FIGS. 47A-47D are schematic, cross-sectional side views of a heart Hshowing a trans-septal or antegrade approach for delivering anddeploying a prosthetic heart valve device 100. As shown in FIG. 47A, aguidewire 24 may be advanced intravascularly using any number oftechniques, e.g., through the inferior vena cava IVC or superior venacava SVC, through the inter-atrial septum IAS and into the right atriumRA. The guiding catheter GC may be advanced along the guidewire 24 andinto the right atrium RA until reaching the anterior side of the atrialseptum AS, as shown in FIG. 47B. At this point, the guidewire 24 may beexchanged for the needle 25, which is used to penetrate through theinter-atrial septum IAS (FIG. 47C). The guiding catheter GC may then beadvanced over the needle 25 into the left atrium LA, as shown in FIG.47D. The guiding catheter GC may have a pre-shaped or steerable distalend to shape or steer the guiding catheter GC such that it will directthe delivery catheter 18 (FIG. 46A) toward the mitral valve.

As an alternative to the trans-septal approach, the mitral valve mayalso be accessed directly through an incision in the left atrium. Accessto the heart may be obtained through an intercostal incision in thechest without removing ribs, and a guiding catheter may be placed intothe left atrium through an atrial incision sealed with a purse-stringsuture. A delivery catheter may then be advanced through the guidingcatheter to the mitral valve. Alternatively, the delivery catheter maybe placed directly through an atrial incision without the use of aguiding catheter.

FIGS. 48A-48C are cross-sectional views of the heart illustrating amethod of implanting a prosthetic heart valve device 100 using atrans-septal approach. Referring to FIGS. 48A-48C together, the distaland 21 of the delivery catheter 18 may be advanced into proximity to themitral valve MV. Optionally, and as shown in FIG. 48A, a guidewire GWmay be used over which catheter 18 may be slideably advanced over aguidewire GW. The sheath 20 of the delivery catheter 18, which containsthe device 100 in a collapsed configuration 106, is advanced through themitral valve annulus AN between native leaflets LF, as shown in FIG.48A. Referring to FIG. 48B, the sheath 20 is then pulled back proximallyrelative to the distal nose cone 27 allowing the device 100 to expandsuch that anchoring member 110 pushes the leaflets LF outwardly to foldbeneath the mitral valve annulus AN. The tips of the ribs 114 engage andmay penetrate into or through the leaflet tissue to further engage thetissue of the annulus AN. After the sheath 20 has been removed and thedevice 100 allowed to expand, the delivery system can still be connectedto the device 100 (e.g., system eyelets, not shown, are connected to thedevice eyelets 180, shown in FIG. 10A) so that the operator can furthercontrol the placement of the device 100 in the expanded configuration102. For example, the device 100 may be expanded upstream or downstreamof the target location then pushed downstream or upstream, respectively,into the desired target location before releasing the device 100 fromdelivery system 10. Once the device 100 is positioned at the targetsite, the pull-wires 30 (FIGS. 46A-46B) may be retracted in a proximaldirection, to detach the device 100 in the deployed configuration 104from the delivery catheter 18. The delivery catheter 18 can then beremoved as shown in FIG. 48C. Alternatively, the device 100 may not beconnected to the delivery system 10 such that the device 100 deploys andis fully released from the delivery system 10.

FIGS. 49A and 49B illustrate another variation for delivering anddeploying one or more prosthetic heart valve devices 100 using aretrograde approach to the mitral valve via the aorta and leftventricle. In this example, the guidewire GW may be advancedintravascularly from a femoral or radial artery or through direct aorticpuncture through the aorta AO and aortic valve AV, and into the leftventricle LV of the heart H (FIG. 49A). A guiding catheter GC, oralternatively, the delivery catheter 18, may be advanced along theguidewire GW until the distal end is positioned within the leftventricle in proximity to the mitral valve MV, as shown in FIGS. 49A and49B. In many arrangements, the guiding catheter GC and/or the deliverycatheter 18 will have a steering mechanism or a pro-shaped distal tipallowing it to be steered around the 180° turn from the aortic valve AVto the mitral valve MV. The distal end of the delivery catheter 18 mayoptionally be advanced at least partially through the mitral valve MVinto the left atrium LA.

FIGS. 50A-SOB illustrate delivery of the device 100 in the collapsedconfiguration 106 to the mitral valve MV in a trans-apical approach.Referring to FIG. 50A, the delivery catheter 18 is advanced through aguiding catheter GC that has been inserted into the left ventricle ofthe heart through a puncture in the left ventricle wall at or near theapex of the heart. The catheter can be sealed by a purse-string suture.Alternatively, the delivery catheter 18 may be placed directly through apurse-string-sealed trans-apical incision without a guiding catheter.The sheath 20 and the device 100 (e.g., in the collapsed configuration106) within the sheath 20 are advanced through the mitral annulus ANbetween native leaflets LF as shown in FIG. 50A. Referring to FIG. 50B,the sheath 20 is pulled proximally such that the device 100 expands tothe expanded and/or deployed configurations 102, 104. The deliverysystem 10 can remain connected to the device 100 (e.g., system eyelets,not shown, are connected to the device eyelets 180, FIG. 10A) afterremoving the sheath 20 so that the operator can control the placement ofthe device 100 while in the expanded configuration 102. The pull-wires30 may be retracted in a proximal direction to release the device 100from the delivery system 10, allowing the delivery system 10 to beremoved and the device to be fully implanted at the mitral valve MV inthe deployed configuration 104. In one embodiment, the device 100 may beexpanded upstream or downstream of the desired target location thenpulled or pushed downstream or upstream, respectively, into the targetlocation before releasing the device 100 from delivery system 10.Alternatively, the device 100 may not be connected to the deliverysystem 10 such that the device 100 deploys and is fully released fromthe delivery system 10.

FIGS. 51A-51B are partial side views of a delivery system 10 wherein aprosthetic heart valve device 100 is mounted on an expandable balloon300 of a delivery catheter 18 in accordance with another embodiment ofthe present technology. Referring to FIGS. 51A and 51B together, thedevice 100 can be mounted on an expendable balloon 300 of a deliverycatheter while in a collapsed configuration 106 and delivered to thedesired location at or near a native mitral valve (FIG. 51A). When thedevice 100 is released from the sheath 20 (FIGS. 46A-46B), the device100 can be expanded to its expanded configuration 102 by inflation ofthe balloon 300 (FIG. 51B). When using a balloon 300 with the deliverysystem 10, the device 100 can be advanced from the delivery shaft 16 toinitially position the device 100 in a target location. The balloon 300can be inflated to fully expand the device 100. The position of thedevice 100 relative to the mitral valve may then be adjusted using thedevice locking hub to position the device into desired implantation site(e.g., just below the annulus of the native mitral valve). In anotherembodiment, the balloon 300 can initially be partially inflated topartially expand the device 100 in the left atrium. The delivery system10 can then be adjusted to push or pull (depending on the approach) thepartially expanded heart valve device 100 into the implantation site,after which the device 100 can be fully expanded to its functional size.In other alternative methods, the anchoring member 110 is aself-expanding construct which is first released from a sheath 20 (FIGS.46A-46B) at the target site to engage the native anatomy, while thevalve support 120 is a balloon-expandable element mounted on a balloon300 which is then expanded to fully deploy the valve support 120 afterthe anchoring member 110 has been released.

In still further embodiments, the valve support 120 of device 100 may beconfigured to be axially movable or detachable from the anchoring member110. In such arrangements, the two components 110, 120 may be loaded inan axially separated configuration within the delivery system 10,thereby reducing the overall profile of the system 10. After delivery tothe target valve site, the components 110, 120 can be assembledtogether. FIGS. 52A-52D show an embodiment of assembling the valvesupport 120 and anchoring member 110 in the heart. As shown in FIG. 52A,the delivery catheter 380 is advanced into the left atrium via a guidingcatheter GC placed through the inter-atrial septum or the atrial wall.The delivery catheter 380 has a split sheath 382, 384 comprising adistal nose cone 382 and a proximal capsule 384. The delivery catheter380 is advanced through the native valve MV until the nose cone 382 ispositioned distally of the native annulus AN (FIG. 52A). The nose cone382 is then advanced further distally while maintaining the position ofthe remainder of the delivery catheter 380 thereby releasing theanchoring member 110 from the nose cone 382 (FIG. 52B). The anchoringmember 110 self-expands outward, engaging the native leaflets LF andfolding them outward beneath the native annulus AN, as shown in FIG.52B. The upstream tips of ribs 114 (FIG. 52B) engage the subannulartissue to anchor the device 100 in position. The sealing member 140 isfixed around the perimeter 113 of the anchoring member 110 and has aconnecting portion 386 extending into the proximal capsule 384 where itis fixed to the valve support 120, which is still constrained within theproximal capsule 384. The delivery catheter 380 is then advanced so asto position the proximal capsule 384 within the anchoring member 110 asshown in FIG. 52C. By advancing the catheter 380 until the sealingmember 140 becomes taught, the proper positioning may be attained. Theproximal capsule 384 is then retracted relative to the nose cone 382 torelease the valve support 120 from the proximal capsule 384. The valvesupport 120 can self-expand into engagement with the downstream end ofanchoring member 110 to couple the two components together. The deliverycatheter 380 may then be withdrawn from the patient.

FIGS. 53A-53H show various mechanisms that may be used for coupling thevalve support 120 to the anchoring member 110 in the process shown inFIGS. 52A-52D. For example, as shown in FIG. 53A, the valve support 120may include a circumferential ridge or detent 388 near its downstreamend that engages in a groove 390 in the anchoring member 110 to inhibitdetachment of the two components. Alternatively, valve support 120 mayhave a hook 392 formed at the downstream end of each post 122 which isconfigured to extend around a downstream end of anchoring member 110,e.g. around either the downstream tip of rib 114 or connectors 116, asshown in FIGS. 53B-53C. For example, the hook 392 may be configured toflex inwardly when it engages the inner surface of the rib 114 as thevalve support 120 is advanced, and be configured to resiliently recoilto its outward configuration when extended beyond the downstream end ofthe rib 114, as shown in FIG. 53C. Optionally, a depth-limiting featuresuch as a stub 394 may extend outwardly from the valve support 120 whichis configured to engage a complementary feature such as a bump or ridge396 on the anchoring member 110 to prevent insertion of the valvesupport 120 beyond a predetermined depth.

In a further embodiment shown in FIGS. 53D-53F, the valve support 120may have a coupling element 398 on its outer surface configured toslideably couple to the anchoring member 110. In a first configuration,the coupling element 398 comprises a loop 400, shown in FIG. 53E,through which a vertical guide member 402 on the anchoring member 110may slide. The anchoring member 110 may have a plurality of such guidemembers 402 extending upwardly from its downstream end at locationsspaced around its circumference. A bump 404 may be formed near thedownstream end of each guide member 402 over which the loop 400 mayslide to inhibit the valve support 120 from sliding back in the upstreamdirection (FIG. 53D). In an alternative configuration, shown in FIG.53F, the guide member 402 has a vertical slot 406 into which a radiallyextending pin 408 on the valve support 120 can extend. The pin 408 mayslide to the downstream end of the slot 406 where it may be urgedthrough a waist 411, which prevents the pin 408 from sliding back in theupstream direction.

In a further embodiment shown in FIGS. 53G-53H, coupling elements 398 onthe valve support 120 are configured to slideably receive the ribs 114,which themselves perform a similar function as the guide members 402(described with respect to FIGS. 53D-53F). As shown in FIG. 53G,coupling of the ribs 114 to the valve support 120 helps restrain theribs 114 in a radially compact configuration when the valve support 120slides axially upward relative to the anchoring member 110. In thearrangement shown in FIGS. 53GG-53H, the delivery of the device 100 maynot require the need for a separate sheath to constrain the ribs 114during the delivery. As shown in FIG. 53H, the valve support 120 mayslide in the downstream direction relative to the anchoring member 110until the ribs 114 assume their radially outward configuration. As withguide members 402, each rib 114 may have a bump 412 formed near itsdownstream end past which coupling element 398 may be urged, but whichthen inhibits valve support 120 from sliding in the upstream direction(FIG. 53H).

FIGS. 54A-55C illustrate a delivery catheter 400 of a delivery system 40in accordance with additional embodiments of the present technology.FIG. 54A is a cross-sectional side view of the delivery system 40 forthe prosthetic heart valve device 100 and FIG. 54B is a partialcross-sectional side view of a distal portion of the delivery system 40shown in FIG. 54A. As shown in FIGS. 54A and 54B, the delivery catheter400 comprises a sheath 402 having an outer wall 403 and a closed distalnose 406 defining a blind annular cavity 408. An inner wall 405 extendsproximally to the proximal end of the catheter (not shown), thus forminga tubular catheter shaft 407 defining an inner lumen extending axiallytherethrough in which a guidewire GW may be slideably positioned. Apiston 412 is slideably disposed in the cavity 408 and has an O-ring 413around its circumference to create a fluid seal with the wall of thecavity 408. A tubular piston shaft 414 extends proximally from piston412 and is slideably mounted over the catheter shaft 407. The pistonshaft 414 is oversized relative to the catheter shaft 407 so as todefine a fluid lumen 416 which is in communication with the cavity 408.The device 26 is retained in its radially collapsed deliveryconfiguration within cavity 408, with piston shaft 414 and cathetershaft 407 extending through the interior of the valve support 120 (shownin FIGS. 55A-55C). Preferably, the device 100 is releasably coupled topiston 412 by, for example, pins (not shown) extending radiallyoutwardly from piston shaft 414.

The sheath 402 may have features that limit its travel. For example, awire (not shown) may tether the protective sheath to a handle on theproximal end of catheter 400. The wire may be attached to an adjustablestop on the handle, allowing the length of piston travel to be adjusted.When fluid is injected into cavity 408, piston 412 will travel untilthis stop is reached. In this manner, the deployment progression can becontrolled.

To ease the retraction of sheath 402 through the valve of the device 100following deployment, a tapered feature may advance to abut the proximalend of the sheath 402 (see FIG. 56). Alternatively, piston 412 may havea taper or soft bumper material affixed directly to the back of piston412 facing in the proximal direction. In this way the proximal side ofthe piston would itself provide an atraumatic leading surface to easeretraction of the sheath 402 through the valve support 120.

Features intended to control and smooth the deployment of device 100 canbe incorporated. For example, a common problem during deployment ofself-expanding stents is a tendency of the deployed device to “pop” orjump forward or backward as the final elements exit the deploymentdevice. Features to prevent the sheath 402 from being thrust forward bythe expanding skeletons of the device 100 may be important in order toprevent accidental damage to the ventricle or other tissue. Suchfeatures may incorporate stops or tethers within the deployment systemdesigned to retain the position of the sheath 402 relative to thedeployed device 100. For example, the proximal edge of the sheath 402could be swaged slightly inward to prevent the piston from exiting thesheath and to precisely locate the taper or bumper features describedabove to ease withdrawal of the system through the deployed valve.Alternatively or additionally, a spring mechanism (not shown) could bebuilt into the delivery system 40 so that when the last features of thedevice 100 leave the sheath 402, the sheath actively retracts slightlyinto the downstream end of the newly deployed device 100.

The operation of the delivery catheter 400 is illustrated in FIGS.55A-55C. The delivery catheter 400 is positioned at the target valvesite using one of the approaches described elsewhere herein. Thedelivery catheter 400 is particularly well suited to placement throughthe native valve from the upstream direction. The catheter 400 isadvanced until the sheath 402 is positioned downstream of the nativeannulus (FIG. 55A). Fluid can then be injected through fluid lumen 416into the cavity 408, distal to the piston 412 (FIG. 55B). This drivesthe sheath 402 distally, releasing the device 100 from the cavity 408(FIG. 55C). The delivery catheter 400 and the device 100 may remain in astationary longitudinal position relative to the native valve while thedevice 100 is deployed, thereby increasing the precision of deployment.In addition, the device 100 may be deployed in a slow and controlledmanner, avoiding sudden and uncontrolled jumps of the device 100.Further, such hydraulic actuation allows the sheath 402 to be moved inincremental steps to only partially deploy the device 100, allowing theoperator to assess its position relative to the native valve andreposition as needed before complete deployment.

In one embodiment, the piston 412 can be hydraulically actuated,however, in another embodiment, the piston 412 could be operated bymanual retraction of the piston shaft 414 or advancement of the sheath402. The delivery catheter 400 may be equipped with a handle on itsproximal end having a retraction mechanism coupled to the piston shaft414 and/or catheter shaft 407. Such a mechanism may use gears or pulleysto provide a mechanical advantage to reduce the force required toretract the piston or advance the sheath.

The delivery catheters in accordance with aspects of the presenttechnology may further be configured to be reversible, to allow thedevice 100 to be retracted beck in to the catheter 400 after a full orpartial deployment. One embodiment of such a catheter is illustrated inFIG. 56, wherein the delivery catheter 400 of FIGS. 54A-55C is adaptedto retract the device 100 back into the sheath 402 after being fully orpartially deployed therefrom. The piston 412 has at least a first pulley420 coupled thereto, while distal nose 406 has at least a second pulley422 coupled thereto. A plurality of additional pulleys 423 may also beprovided at locations around the circumference of the piston 412 foradditional mechanical assistance. A cable 424, which may comprise alength of wire or suture, extends through the fluid lumen 416 and cavity408, passes around first and second pulleys 420, 422 and any additionalpulleys 423, and is secured to piston 412. The device 100 can bereleasably coupled to the piston shaft 414 by a plurality of pins 426extending radially from the piston shaft 414 into engagement with thedevice 100, preferably near a downstream end 428 thereof.

To deploy the device 100, the delivery catheter 400 of FIG. 56 operatessimilarly as described above in connection with FIGS. 55A-55C; however,in an additional embodiment and before the downstream end 428 has beenfully released from the sheath 402, the operator can checks the locationof the device 100. Upon deployment, the upstream end 430 of the device100 will expand toward its expanded configuration. An operator can view,using ultrasound, fluoroscopy, MRI, or other means, the position andshape of the deployed device 100 in the native tissue. Followingpositioning, the sheath 402 may be further advanced relative to thepiston 412 to fully deploy the device 100 from the sheath 402, whereuponthe downstream end 428 fully expands and pins 426 are disengaged fromdevice 100. In situations where the operator desires to recover thedevice 100 back into the sheath 402 for repositioning or other reasons,the cable 424 is pulled so as to move the piston 412 in the distaldirection relative to the sheath 402. The pins 426 pull the device 100with the piston 412 back into the sheath 402 and the device 100 iscollapsed as it is pulled in the sheath 402. The delivery catheter 400may then be repositioned and the device redeployed.

In one embodiment, the prosthetic heart valve device 100 may bespecifically designed for a specific approach or delivery method toreach the mitral valve, or in another embodiment, the device 100 may bedesigned to be interchangeable among the approaches or delivery methods.

Additional Embodiments of Prosthetic Heart Valve Devices, DeliverySystems and Methods

FIGS. 57A-57E are isometric views of prosthetic heart valve devices 600shown in an expanded configuration 602 and configured in accordance withadditional embodiments of the present technology. The prosthetic heartvalve devices 600 include features generally similar to the features ofthe prosthetic heart valve device 100 described above with reference toFIGS. 10A-56. For example, the prosthetic heart valve device 600includes the valve support 120 configured to support a prosthetic valve130 and an anchoring member 610 coupled to the valve support 120 in amanner that mechanically isolates the valve support 120 from forcesexerted upon the anchoring member 610 when implanted at the nativemitral valve. However, in the embodiments shown in FIGS. 57A-57E, anupstream region 612 of the anchoring member 610 is coupled to the valvesupport 120 such that a downstream region 611 of the anchoring member610 is configured to engage native tissue on or downstream of theannulus so as to prevent migration of the device 600 in the upstreamdirection.

FIGS. 57A and 57B illustrate embodiments of the device 600 wherein theanchoring member 610 includes a plurality of longitudinal ribs 614coupled to the upstream end 121 of the valve support 120 and extendingin a downstream to distal direction. As shown in FIG. 57A, the ribs 614can project radially outward away from the longitudinal axis 101 at thedownstream region 611 of the anchoring member 610 such that thedownstream region 611 is flared outward for engaging subannular tissuebelow the mitral annulus. FIG. 57B illustrates an embodiment of thedevice 600 having an anchoring member 610 with an upward-facing lip 617at the downstream region. In this embodiment, the ribs 614 can be formedsuch that the downstream region is generally flared outwardly from thelongitudinal axis 101 but the tips 615 of the ribs 614 reorient to pointin an upstream direction at the lip 617. The lip 617 may assist theanchoring member 610 in engaging subannular tissue and can be configuredto include tissue engaging elements (not shown) as described above withrespect to device 100. The anchoring member 610 can also be coupled tothe valve support 120 at a position desirable for positioning the valvesupport 120 and prosthetic valve 130 within the native valve. Forexample, FIG. 57C illustrates an embodiment of the device 600 in whichthe anchoring member 610 can be coupled to the valve support 120 at alocation downstream from the upstream end 121.

Referring to FIGS. 57A-57C together, the anchoring member 610 can have afirst cross-sectional dimension D_(C1) at the upstream region 612 thatis less than a second cross-sectional dimension D_(C2) at the downstreamregion 611. Additionally, the valve support 120 is radially separatedfrom the downstream region 611 of the anchoring member 610 such thatwhen the device 600 is deployed, the downstream region 611 can deforminwardly without deforming the upstream portion of the valve support120. Additionally, the anchoring member 610 can have a generally oval orD-shape, or other irregular shape such as those described above withrespect to FIGS. 16A-17C, while the valve support 120 can be generallycylindrical in shape. In such embodiments, the second cross-sectionaldimension Dc can be greater than a corresponding cross-sectionaldimension (e.g., MVA1 or MVA2) of the annulus of the native mitral valve(FIG. 5C).

FIG. 57D illustrates yet another embodiment of the device 600 in anexpanded configuration 602. As shown, the valve support 120 can includea flange 620 at the downstream end 123 of the valve support 120. Theflange 620 can extend radially outward from the longitudinal axis 101 atthe downstream end 123 to radially engage subannular tissue. Theanchoring member 610 can include a plurality of ribs 614 coupled to theupstream end 121 of the valve support 120 and extending radially outwardin the downstream direction to attach to an outer rim 622 of the flange620. The anchoring member 610 can be configured to engage subannulartissue, such as inward-facing surfaces of the leaflets. In thisembodiment, the ribs 614 can be flexible such that deformation of theanchoring member 610 between the coupling at the upstream region 612 andthe coupling to the flange 620 at the lower region 611 will notsubstantially deform the valve support 120 wherein a prosthetic valve isconnected.

FIG. 57E as a schematic cross-sectional view of the prosthetic heartvalve device 600 of FIG. 57A implanted at a native mitral valve MV inaccordance with an embodiment of the present technology. As shown, theflared downstream region 611 of the anchoring member 610 can engage thesubannular tissue, e.g., inward-facing surfaces of the leaflets LF, asubannular surface, etc. The ribs 614 can incorporate tissue engagingelements 170 on the rib tips 615 for penetrating and/or partiallypenetrating the tissue. Further, the anchoring member 610 can expandradially outward to seal (not shown) against the tissue to preventmigration of the device 600 in the upstream or downstream directionand/or to prevent paravalvular leaks between the tissue and the device600. Accordingly, the device 600 can incorporate one or more sealingmembers 140 as described above with respect to device 100. Additionally,the device 600 can also include an atrial extension member or atrialretainer 410 (shown in dotted lines) as described above with respect tothe device 100. The atrial retainer, if present, can be configured toengage tissue above the annulus AN such as a supra-annular surface orsome other tissue in the left atrium LA to inhibit downstream migrationof the device (e.g., during atrial systole).

FIGS. 58A-58D are cross-sectional views of a heart showing a method ofdelivering a prosthetic heart valve device 600 to a native mitral valveMV in the heart using a trans-apical approach in accordance with anotherembodiment of the present technology. Referring to FIG. 58A, thedelivery catheter 18 is advanced through guiding catheter (not shown)which enters the left ventricle LV of the heart through a puncture inthe left ventricle wall at or near the apex of the heart and is sealedby a purse-string suture. Alternatively, the delivery catheter 18 may beplaced directly through a purse-string-sealed trans-apical incisionwithout a guiding catheter. The sheath 20, containing a collapsed device600, 606 (shown in FIG. 58B), is advanced through the mitral annulus ANbetween native leaflets LF as shown in FIG. 58A. Referring to FIGS.58B-58D together, the sheath 20 is pulled proximally to allow the device600 to expand to the expanded and/or deployed configurations 602, 604(FIGS. 58C and 58D).

Although the sheath 20 can be retracted and the device 600 allowed toexpand, the delivery system can remain connected to the device 600(e.g., system eyelets, not shown, are connected to the device eyelets,not shown) such that the operator can control the placement of thedevice 600 while in the expanded configuration 602 (FIGS. 58C and 58D).For example, as the sheath 20 is disengaged from the device 600, theupstream region 612 of the anchoring member 610 can remain collapsedwithin the sheath preventing the anchoring member 610 from fullyexpanding (FIG. 58C). During this phase of the delivery, the position ofthe device 600 within the mitral valve area can be adjusted or altered.After the device 600 is located at the target site, the sheath 20 can befully removed from the device 600 and the anchoring member 610 of thedevice 600 can expand outwardly at the downstream region 611 to engagesubannular tissue, such as the leaflets LF, and to retain the device 600in the desired target location. The pull-wires (not shown) may beretracted in a proximal direction to release the device 600 from thedelivery system, allowing the delivery system to be removed and thedevice to be fully implanted at the mitral valve MV in the deployedconfiguration 104. Alternatively, the device 600 may be expandedupstream or downstream of the desired target location then pulled orpushed downstream or upstream, respectively, into the target locationbefore releasing the device 600 from delivery system.

FIGS. 59A-59C are isometric views of prosthetic heart valve devices 700shown in an expanded configuration 702, and FIG. 59D is a schematiccross-sectional view of the prosthetic heart valve device 700 implantedat a native mitral valve configured in accordance with furtherembodiments of the present technology. The prosthetic heart valvedevices 700 include features generally similar to the features of theprosthetic heart valve devices 100 and 600 described above withreference to FIGS. 10A-58D. For example, the prosthetic heart valvedevice 700 includes the valve support 120 configured to support aprosthetic valve 130 and a first anchoring member 610 coupled to thevalve support 120 in a manner that mechanically isolates the valvesupport 120 from forces exerted upon the first anchoring member 610 whenimplanted at the native mitral valve. Particularly, the upstream region612 of the first anchoring member 610 is coupled to the valve support120 and the downstream region 611 of the first anchoring member 610 isconfigured to flare outwardly to engage native tissue on or downstreamof the annulus so as to prevent migration of the device 600 in theupstream direction. However, in the embodiments shown in FIGS. 59A-59D,the device 700 also includes a second anchoring member 710 having adownstream region 711 coupled to the valve support 120, and an upstreamregion 712 extending radially outward in the upstream direction.Accordingly, the device 700 includes both the first and second anchoringmembers 610 and 710 for engaging tissue on or under the annulus of themitral valve.

Referring to FIGS. 59A-59D together, the first anchoring member 610 canhave the first cross-sectional dimension D_(C1) at the upstream region612 that is less than the second cross-sectional dimension D_(C2) at thedownstream region 611. The second anchoring member 710 can have a thirdcross-sectional dimension D_(C3) at the upstream region 712 that isgreater than a fourth cross-sectional dimension D_(C4) at the downstreamregion 711. In some embodiments, the third cross-sectional dimensionD_(C3) is less than the second cross-sectional dimension D_(C2) suchthat the second anchoring member 710 can be partially surrounded by thefirst anchoring member 610 (FIG. 59A). In such an embodiment, theupstream region 712 can apply radial outward pressure against an innerwall (not shown) of the first anchoring member 610 and further supportthe fixation of the first anchoring member 610 to the tissue on or underthe annulus. In another embodiment shown in FIG. 59B, the thirdcross-sectional dimension D_(C3) can be approximately the same as thesecond cross-sectional dimension D_(C2) such that the first and secondanchoring members 610, 710 meet at a flared junction 740. In oneembodiment, the first and second anchoring members 610 and 710 can becoupled at the flared junction 740; however, in other embodiments, thefirst and second anchoring members 610 and 710 are not coupled. FIG. 59Cshows another embodiment of the device 700 wherein the downstream region615 of the first anchoring member 610 is separated from the upstreamregion 713 of the second anchoring member 710 by a gap 750. In oneembodiment, the device 700 shown in FIG. 59C can be implanted at thenative heart valve such that the first anchoring member 610 can engagesupra-annular tissue or other cardiac tissue upstream of the annulus andthe second anchoring member 710 can engage subannular tissue or othercardiac tissue downstream of the annulus such that the annulus isretained or captured within the gap 750.

In a further embodiment illustrated in FIG. 59D, the thirdcross-sectional dimension D_(C3) is greater than the secondcross-sectional dimension D_(C2) such that the second anchoring member710 can partially surround the first anchoring member 610. In such anembodiment, the downstream region 611 of the first anchoring member 610can apply radial outward pressure against an inner wall 741 of thesecond anchoring member 710 and further support the fixation of thesecond anchoring member 710 to the tissue on or under the annulus AN.

Additionally, the valve support 120 can be radially separated from thedownstream region 611 of the first anchoring member 610 as well as theupstream region 712 of the second anchoring member 710 such that whenthe device 700 is deployed, the downstream region 611 and/or theupstream region 712 can deform inwardly without substantially deformingthe valve support 120 or without deforming a support region 734 of thevalve support 120 supporting the prosthetic valve 130. Additionally, thefirst and second anchoring members 610, 710 can have a generally oval orD-shape, or other irregular shape such as those described above withrespect to FIGS. 16A-17C, while the valve support 120 can be generallycylindrical in shape. Moreover, additional features may be incorporatedon the device 700, such as sealing membranes 140 and tissue engagingelements 170 as described above with respect to the device 100.

FIGS. 60A-60B are cross-sectional side views of a distal end of adelivery catheter 18 for delivering the prosthetic heart valve device700 of FIG. 59C to a native mitral valve in the heart in accordance withanother embodiment of the present technology. As shown in FIGS. 60A-60Bthe prosthetic heart valve device 700 is collapsed into a deliveryconfiguration 706 and retained within a two portion delivery sheath 70at the distal end of the catheter 18 (FIG. 60A). Upon delivery of thedistal end of the catheter 18 to the desired location at or near anative mitral valve, the device 700 can be released from the two portionsheath 70 by retracting an upper portion 72 in a distal direction and/orretracting a lower portion 74 in a proximal direction (shown with arrowsin FIG. 60A) thereby separating the sheath and exposing the collapseddevice 700 from within the sheath 70. In one embodiment, the device 700can self-expand to its expanded configuration 702 following retractionof the sheath 70 (FIG. 60B). As illustrated in FIG. 60B, when the sheath70 is retracted in both the proximal and distal directions, the firstand second anchoring members 610, 710 can self-expand outwardly toengage the native tissue. When using a balloon 300 to expand the supportvalve 120, the balloon 300 can be inflated to fully expand the device700.

FIG. 61 illustrates a prosthetic heart valve device 800 configured inaccordance with another embodiment of the present technology. FIG. 61 isa side view of the device 800 that includes features generally similarto the features of the prosthetic heart valve devices 100, 600, 700described above with reference to FIGS. 10A-60B. For example, the device800 includes a support valve 120 having upstream and downstream ends121, 123 and an interior in which a valve (not shown) may be coupled.The device also includes first and second anchoring members 810 and 850.The first anchoring member 810 has a first flared upstream portion 812and a first downstream portion 811 that is coupled to an outer orexterior surface 127 of the valve support 120. The first flared upstreamportion 812 can be mechanically isolated from the valve support 120.Additionally, the first flared upstream portion 812 can be configured toengage supra-annular tissue of the native mitral valve. The secondanchoring member 850 can be configured to at least partially surroundthe first anchoring member 810 and to have a second flared upstreamportion 852 for engaging the subannular tissue of the native mitralvalve. The second anchoring member 850 can also have a second downstreamportion 851 coupled to the outer surface 127 of the valve support 120 ina manner that mechanically isolates the valve support 120 from at leastthe second upstream portion 852.

As shown in FIG. 61, the first anchoring member 810 can have a pluralityof first longitudinal ribs 814 and the second anchoring member 850 canhave a plurality of second longitudinal ribs 854. In one embodiment,each of the individual first ribs 814 are longer than each of theindividual second ribs 854 such that the first anchoring member 810 hasa height H_(AM1) greater than a height H_(AM2) of the second anchoringmember 850. Accordingly, the height H_(AM2) can be selected to orientthe second anchoring member 850 to engage subannular tissue, while theheight H_(AM1) can be selected to orient the first anchoring member 810to extend through the mitral valve from the left ventricle to engagesupra-annular tissue in the left atrium.

FIG. 61 illustrates one embodiment of the device 800 that can include alower ring 808 on which the ribs 814, 854 can be interconnected. Thelower ring 808 can allow the ribs 814, 854 to expand radially outwardaway from the valve support 120 at the upstream portions 812, 852. Thedevice 800 can also include a first upper ring member 816 coupled to theplurality of first longitudinal ribs 814. The first upper ring member816 can be shaped and or patterned to have a downward oriented rim 818for engaging supra-annular tissue. The device can further include asecond upper ring member 856 coupled to the plurality of secondlongitudinal ribs 854. The second upper ring member 856 can be shapedand or patterned to have an upward oriented rim 858 for engagingsubannular tissue.

FIGS. 62A-62C are partial cross-sectional side views of a distal end ofa delivery system 10 showing delivery of the prosthetic heart valvedevice 800 of FIG. 61 at a mitral valve MV in accordance with anotherembodiment of the present technology. The device 800 can be retained ina collapsed configuration 806 within a sheath 20 of the delivery system(FIG. 62A). When the distal end of the delivery system engages thetarget location, the sheath 20 can be retracted proximally from thedevice 800, thereby releasing the features of the device 800 to expandinto the expanded configuration 102 (FIGS. 62B-62C). As shown in FIG.62B, the second anchoring member 850 can be released first from theretracting sheath 20 and the upward oriented rim 858 of the second upperring member 856 can be positioned to engage the subannular tissue. Thesheath 20 can prevent the first anchoring member 810 from disengagingfrom the delivery system 10 and/or moving outside the sheath 20 untilthe rim 858 of the second anchoring member 850 is moved into position toengage the subannular tissue. Referring to FIG. 62C, a plunger 11 canengage the first anchoring member 810 (as shown by downward arrow inFIG. 62B) and/or the sheath 20 can be disengaged/retracted (shown byupward arrow in FIG. 62C) from the first anchoring member 810 therebyallowing the second anchoring member 850 to move radially outward to theexpanded configuration 802. The downward oriented rim 818 of the firstupper ring member 816 can be positioned to engage the supra-annulartissue (FIG. 62C). Once deployed, the rings 816, 856 can sandwich theannulus AN of the mitral valve and inhibit movement of the device 800 inboth upstream and downstream directions.

FIG. 63 is an isometric side view of a prosthetic heart valve device 900in accordance with a further embodiment of the present technology. Thedevice 900 includes features generally similar to the features of theprosthetic heart valve devices 100, 600, 700 and 800 described abovewith reference to FIGS. 10A-62C. For example, the device 900 includes asupport valve 120 having upstream and downstream ends 121, 123 and aninterior in which a valve (not shown) may be coupled. The device 900includes an anchoring member 910 that has a flared upstream portion 912and a downstream portion 911 coupled to the valve support 120. However,the device 900 also includes upper and lower rings 950, 952 and aplurality of flexible annulus engaging elements 970 distributed around acircumference 980 of the anchoring member 910 and configured to couplethe upper ring 950 to the lower ring 952. The flexible annulus engagingelements 970 can have a shape such as a C-shape or U-shape that isoriented to have an open portion outward from the device 900 such thatthe native annulus AN can be engaged in recesses 971 of the annulusengaging elements 970. The annulus engaging elements 970 can alsoinclude points 972, 973 for engaging and potentially piercingsupra-annular and subannular tissue, respectively. The annulus engagingelements 970 can be suitably flexible to bend in a manner that bringsthe points 972, 973 close together for securing the device 900 to theannulus AN when the device 900 is deployed.

FIGS. 64A-64B illustrate a method for deploying the device 900 at thenative mitral valve. Referring to FIGS. 63 and 64A-64B together, theannulus engaging elements 970 can be generally relaxed or have a widerecess 971 in an open state 903. As such, the upper ring 950 can restabove the lower ring 952 a first distance DR, when the elements 970 arein the open state 903. The device 900 can also include a plurality ofpull-wires 974 that are slideably engaged with the upper ring 950 (e.g.,through holes 975) and secured to the lower ring 952. When the wires 974are pulled in an upward or upstream direction, the lower ring 952 movesin an upward/upstream direction toward the upper ring 950. As the lowerring 952 approaches the upper ring 950, the annulus engaging elements970 can bend such that the points 972, 973 are brought closer togetherand/or engage or pierce the annulus tissue (FIG. 64B). Accordingly, whenthe device 900 is in the deployed state 904, the upper ring 950 can beheld by the pull-wires 974 at a second distance D_(R2) above the lowerring 952, wherein the second distance D_(R2) is less than the firstdistance D_(R1).

FIGS. 64C-64D show an alternative arrangement of the pull-wires 974 inwhich the wires 974 are secured to the upper ring 950 and are slideablyengaged with the lower ring 952 (e.g., through holes 976). Thepull-wires 974 can also be slideably engaged with the upper ring 950(e.g., such as through holes 975) such that the pull-wires can be pulledin an upward direction to bring the rings 950, 952 closer together inthe deployed state 904.

FIG. 65A is an isometric side view of a prosthetic heart valve device1000 in accordance with a further embodiment of the present technology.The device 1000 includes features generally similar to the features ofthe prosthetic heart valve devices 100, 600, 700, 800 and 900 describedabove with reference to FIGS. 10A-64D. For example, the device 1000includes a support valve 120 having upstream and downstream ends 121,123 and an interior 134 in which a valve 130 may be coupled. However,the device 1000 includes an inflatable anchoring member 1010 coupled toand at least partially surrounding the valve support 120. The inflatableanchoring member 1010 can be configured to inflate/expand upondeployment and engage native tissue at the desired target location. Asshown in FIG. 65A, the inflatable anchoring member 1010 can have one ormore fillable chambers 1014 for receiving a fill substance such as asolution (e.g., saline or other liquid) or gas (e.g., helium, CO₂ orother gas) following implantation of the device 1000. In otherembodiments, the fillable chambers 1014 can be filled with a hardeningmaterial (e.g., epoxy, cement, or other resin).

In one embodiment, the fillable chambers 1014 and/or the anchoringmember 1010 can be formed of polytetrafluoroethylene (PTFE), urethane,or other expendable polymer or biocompatible material. The fillablechambers 1014 can have a predetermined shape such that the fillablechambers 1014, when inflated, form fixation elements 1015 for engagingthe native anatomy. For example, the fixation elements 1015 can includea supra-annular flange 1016 for engaging a surface of the annulus ANwithin the left atrium LA. The elements 1015 may also include subannularflanges 1018 for engaging subannular tissue and/or arms 1020 forengaging leaflets LF (e.g., behind leaflets). Accordingly, the chambers1014 can be incorporated or shaped such that the anchoring member 1010engages supra-annular tissue, subannular tissue, leaflets or othertissue at or near the mitral valve MV while mechanically isolating thevalve support 120 from distorting diastolic and systolic forcesgenerated in the heart and particularly radial forces exerted on thedevice 1000 at or near the native mitral valve. For example, followingdeployment, the inflatable anchoring member 1010 can absorb pulsatileloading and other forces generated against the device 1000 such thatdeformation of the anchoring member 1010 does not substantially deformthe valve support 120.

FIG. 65B is a partial cross-sectional side view of a distal end of adelivery system 10 suitable for delivery of the prosthetic heart valvedevice 1000 of FIG. 65A in accordance with another embodiment of thepresent technology. As shown in FIG. 65B, the delivery system 10 caninclude a delivery catheter 18 configured to retain the device 1000 in acollapsed configuration 1006. In the collapsed configuration 1006, theinflatable anchoring member 1010 is deflated. The delivery system 10 canalso include a fill tube 90 suitable to deliver the fill substance whenthe device 1000 is in position and ready for deployment. Referring toFIGS. 65A-65B together, and in one embodiment, the inflatable anchoringmember 1010 can be partially filled with the fill substance such thatthe position of the device 1000 at the implant site can be adjusted toalign the fixation elements 1015 with the native tissue features beforefully expanding and/or inflating the anchoring member 1010 to hold thedevice 1000 in place at the target location.

FIGS. 66A-66D are cross-sectional views of prosthetic heart valvedevices 1100 having tillable chambers 1114 in accordance with additionalembodiments of the present technology. Similar to the device 1000discussed with respect to FIGS. 65A-65B, the devices 1100 includefeatures such as the valve support 120 having an interior 134 in which avalve 130 is coupled and include an expandable anchoring member 1110coupled to the valve support 120 in a manner that mechanically isolatesthe valve support 120 from forces exerted upon the anchoring member 1110when implanted at the native mitral valve. The anchoring member 1110 canbe coupled to the valve support 120 such that an upstream region 1112 ofthe anchoring member 1110 is configured to engage native tissue on ordownstream of the annulus so as to prevent migration of the device 1100in the upstream direction. In the embodiments shown in FIGS. 66A-66D,the devices 1100 can also include one or more fillable chambers 1114configured to expand and/or inflate in an outward direction to supportan outward expansion of the anchoring member 1100 (FIGS. 66A, 66C-66D),or to engage native tissue (FIG. 66B). In one embodiment, the fillablechambers 1114 and/or the anchoring member 1010 can be formed ofpolytetrafluoroethylene (PTFE), urethane, or other expandable polymer orbiocompatible material. The tillable chambers 1114 can have apredetermined shape such that the tillable chambers 1114, when inflated,form fixation elements for engaging the native anatomy (as shown in FIG.66B) or for engaging the anchoring member 1110 (as shown in FIGS. 66A,66C and 66D).

Referring to FIG. 66A, the fillable chamber 1114 can be chambers 1114created with a space between the valve support 120 and the anchoringmember 1110. Following expansion of the device 1100, the fillablechambers 1114 can be filled with a fill substance such as a solution(e.g., saline or other liquid) or gas (e.g., helium, CO₂ or other gas).In other embodiments, the fillable chambers 1114 can be filled with ahardening material (e.g., epoxy, cement, or other resin). In otherembodiments, the fillable chambers 1114 can be a separate component ofthe device 1100, such a ring-shaped chamber 1150 coupled to an outersurface 1142 of the anchoring member 1110 (FIG. 66B) or to an innersurface 1141 of the anchoring member 1110 or to an exterior surface 127of the support valve 120. In FIGS. 66C-66D, for example, the ring-shapedchamber 1150 can provide additional support to the anchoring member 1110such that inward deformation is counteracted by the presence of thering-shaped chamber 1150. Additionally, as shown in FIG. 66D, thetillable chamber 114 can be a ring-shaped chamber 1150 that deforms theanchoring member 1110 in an outward direction against the native tissue.

In accordance with another aspect of the present technology, FIGS.67A-67B illustrates other embodiments of a prosthetic heart valve device1200. Referring to FIGS. 67A-67B together, the device 1200 can include aradially expandable anchoring member 1210 configured to engage nativetissue on or downstream of the annulus, and a support valve 120 and/or aprosthetic valve 130 coupled to an interior portion 1234 of theanchoring member 1210. The anchoring member 1210 can have a firstlongitudinal length L_(L1) on a posterior leaflet-facing side 1222 ofthe anchoring member 1210 and have a second longitudinal length L_(L2)on an anterior leaflet-facing side 1224 of the anchoring member 1210. Asshown in FIG. 67A, the first length L_(L1) is greater than the secondlength L_(L2) such that occlusion of a left ventricle outflow tract(LVOT) is limited. Accordingly, in one embodiment, the posteriorleaflet-facing side 1222 can provide suitable fixation and support forthe anchoring member 1210 by engaging the thicker ventricular wall andtissue on the posterior leaflet side of the mitral valve. Concurrently,the shorter anterior leaflet-facing side 1224 of the anchoring member1210 can have sufficient sealing and conformability to engage theanterior leaflet and/or subannular tissue aligned with the anteriorleaflet of the native valve.

Optionally, the device 1200 can also include one or more stabilizingelements such as an arm 1250 coupled to the anchoring member 1210 forengaging a leaflet and/or a subannular surface. In FIG. 67A, the arm1250 can be coupled to a downstream end 1223 of the anchoring member1210 on the posterior leaflet-facing side 1222 of the anchoring member1210 and be configured to extend behind the posterior leaflet. In oneembodiment, the arm 1250 can be configured to sandwich the posteriorleaflet between the arm 1250 and the anchoring member 1210.

In FIG. 67B, the device 1200 can include first and second arms(individually identified as 1250 a and 1250 b) coupled to the anchoringmember 1210 for engaging leaflets and/or subannular surfaces. Forexample, the first arm 1250 a can be coupled to the downstream end 1223at the anterior leaflet-facing side 1224 of the anchoring member 1210with extension 1251 a and can be configured to further extend behind theanterior leaflet. The second arm 1250 b can be coupled to the downstreamend 1223 of the posterior leaflet-facing side 1222 of the anchoringmember 1210 with extension 1251 b and be configured to extend behind theposterior leaflet. In the illustrated embodiment, the extensions 1251 aand 1251 b can vary with respect to each other and be selected based onthe anatomy of the target tissue. In other embodiments, not shown, thearm 1250 and or the anchoring member 1210 can include tissue engagingelements as described above with respect to device 100 for furtherpositioning and stabilizing of the device 1200 at the desired targetlocation. One of ordinary skill will recognize that the valve support120 can also be uneven or have sides having different lengths such thatthe valve support will not substantially occlude the left ventricleoutflow tract (LVOT).

FIGS. 68A-68B are side views of prosthetic heart valve devices 1300shown in an expanded configuration 1302 and configured in accordancewith an additional embodiment of the present technology. The prostheticheart valve devices 1300 include features generally similar to thefeatures of the prosthetic heart valve device 100 described above withreference to FIGS. 10A-56. For example, the prosthetic heart valvedevice 1300 includes the valve support 120 configured to support aprosthetic valve 130 and an anchoring member 110 coupled to the valvesupport 120 in a manner that mechanically isolates the valve support 120from forces exerted upon the anchoring member 110 when implanted at thenative mitral valve. However, in the embodiments shown in FIGS. 68A-68B,the device 1300 also includes a positioning element 1350 configured toadjust or maintain a desired position of the device 1300 within or nearthe native mitral valve (e.g., away from the LVOT). The positioningelement 1350 can be coupled to the downstream portion 111 of theanchoring member 110 (as shown in FIGS. 68A-68B), the upstream portion112 of the anchoring member 110, or to the valve support 120, at anelement connection point 1352 and extend outward from the elementconnection point 1352 to engage ventricular tissue at a desiredlocation. In one embodiment, the positioning element 1350 can extendoutward from the device 1300 in a direction approximately transverse tothe longitudinal axis 101. In other embodiments, not shown, thepositioning element 1350 can extend outwardly from the device 1300 at anobtuse or an acute angle relative to the longitudinal axis 101 forengaging the ventricular tissue at the desired location.

In the embodiment shown in FIG. 68A, the positioning element 1350 caninclude a positioning arm 1354 and a tissue engaging portion 1356coupled to the distal arm end 1358 of the positioning arm 1354. Thepositioning arm 1354 and tissue engaging portion 1356 together canextend a desired positioning distance D_(P1) away from the elementconnection point 1352 on the device 1300 (e.g., from the anchoringmember 110) such that the distal end 1360 of the positioning element1350 can engage ventricular tissue, such as a ventricular wall. In someembodiments, the positioning distance D_(P1) can be selected to begreater than a distance between the implanted device 1300 and theventricular tissue such that the positioning element 1350, afterengaging the ventricular tissue, extends the distance between theimplant device 1300 and the ventricular tissue. In this way, the device1300 can be positioned, aligned and maintained in an alternate positionwithin or near the mitral valve.

The tissue engaging portion 1356 can be configured to contact theventricular tissue, or other tissue (e.g., annular tissue, leaflettissue, etc.), in an atraumatic manner such that the tissue engagingportion 1356 does not penetrate or pierce the tissue. In one embodiment,the tissue engaging portion 1356 can be resilient and/or be formed of ashape memory material (e.g., Nitinol) that can be partially deformedwhen engaging tissue. For example, the tissue engaging portion 1356 canbe configured to absorb forces generated by the ventricular tissue(e.g., ventricular wall) during e.g., systole, without translatingmovement or altering a desired position of the device 1300 with respectto the native mitral valve. In other embodiments, the distal end 1360 ofthe positioning element 1350 can have other shapes or configurationsthat penetrate the ventricular tissue. The device 1300 can include oneor more positioning elements 1350 disposed around the device 1300 forpositioning and/or maintaining a desired position of the device 1300with respect to native anatomy. For example, it may be desirable toincrease the distance between the device 1300 and the left ventricularoutflow tract (LVOT), and a positioning element 1350 can be configuredto engage ventricular tissue to push or encourage the device 1300 aselected distance away from the LVOT.

In the embodiment shown in FIG. 68B, the positioning element 1350 caninclude a looped tissue engaging portion 1358 coupled to the device 1300at the connection point 1352. The looped tissue engaging portion 1358can extend the desired positioning distance Dpi away from the elementconnection point 1352 on the device 1300 (e.g., from the anchoringmember 110) such that the distal end 1360 of the looped tissue engagingportion 1358 can engage ventricular tissue, such as a ventricular wall.The looped tissue engaging portion 1358 can be configured to absorbradially contracting forces or other forces generated and transmitted bythe ventricular tissue (e.g., within the left ventricle) such that theyare not transmitted to or can change the position of the device 1300with respect to the native heart valve. Accordingly, the device 1300 canbe positioned, aligned and maintained in an alternate position within ornear the mitral valve.

In another embodiment, not shown, a positioning structure, separate fromthe prosthetic heart valve device 100, can be implanted or otherwisepositioned in the left ventricle (e.g., at or near the LVOT) and whichcan be configured to engage portions of the device 100, such as theanchoring member 110. Accordingly, such a positioning structure can beprovided to prevent the device 100 from obstructing or partiallyobstructing the LVOT. In one embodiment, not shown, the positioningstructure could be a stent-like cylinder or cage that expands intoengagement with the ventricular wall and keeps the LVOT clear to allowblood to flow freely from the left ventricle through the aortic valve.In one example, the positioning structure could be delivered by catheterthat is inserted through the aorta and the aortic valve into the leftventricle, or through the apex or the left atrium via the same deliverycatheter used for delivering and implanting the device 100.

FIGS. 69A-69E are cross-sectional and side views of prosthetic heartvalve devices 1400 shown in an expanded configuration 1402 andconfigured in accordance with an additional embodiment of the presenttechnology. The prosthetic heart valve devices 1400 include featuresgenerally similar to the features of the prosthetic heart valve devices100, 600 described above with reference to FIGS. 10A-57E. For example,the prosthetic heart valve devices 1400 include the valve support 120configured to support a prosthetic valve 130 and an anchoring member 110or 610 coupled to the valve support 120 in a manner that mechanicallyisolates the valve support 120 from forces exerted upon the anchoringmember 110 when implanted at the native mitral valve. However, in theembodiments shown in FIGS. 69A-69E, the devices 1400 also includes a anexpandable tissue-engaging ring 1450 coupled to a tissue engagingportion of the anchoring member 110 and configured to provide additionalcontact surface for engaging native tissue at or near the annulus of theheart valve.

In one embodiment, shown in FIGS. 69A-69B, the expandabletissue-engaging ring 1450 can be coupled to an upstream perimeter 113 ofthe anchoring member 110 and have a tissue-engaging surface 1452 facingin an outward direction relative to the device 1400. In someembodiments, the tissue-engaging surface 1452 can have tissue-engagingelements 170 for engaging and/or piercing the tissue. In anotherembodiment, shown in FIG. 69C, the expandable tissue-engaging ring 1450can be coupled to a downstream perimeter 115 of the anchoring member1410 and have a tissue-engaging surface 1452 facing in an outwarddirection relative to the device 1400. In another embodiment shown inFIG. 69D, the expandable tissue-engaging ring 1450 may include aplurality of fibrous elements 1454 (e.g., fiber elements) that can beconfigured to encourage tissue ingrowth, thrombus and/or be configuredto provide a seal between the anchoring member 110 and the tissue. Invarious arrangements, the expandable tissue-engaging ring 1450 canexpand and contract between various deployment and deliveryconfigurations.

FIG. 69E shows another embodiment of the prosthetic heart valve device1400 having the expandable tissue-engaging ring 1450. In thisembodiment, the device 1400 can have a valve support 120 coupled to afirst anchoring member 110 and a second anchoring member. In oneembodiment, the first anchoring member 110 can be coupled to the valvesupport 120 at the downstream end 123 and extends outward and in anupstream direction. The second anchoring member 1410 can be coupled tothe valve support 120 at the upstream end 121 and extend outward and ina downstream direction. The expandable tissue-engaging ring 1450 can becoupled to the distal portions of the first and second anchoring members110, 1410 and have the tissue-engaging surface 1452 facing in an outwarddirection relative to the device 1500 for engaging tissue at or near theannulus AN or leaflets LF. In a particular example, the expandabletissue-engaging ring 1450 can have a first end 1460 coupled to anupstream end 1461 of the first anchoring member 110. The expandabletissue-engaging ring 1450 can also have a second end 1470 coupled to adownstream end 1471 of the second anchoring member 1410. Thetissue-engaging surface 1452 may also include tissue engaging elements170 for engaging and/or piercing the tissue at the target location.

Referring to FIGS. 69A-69E together, the outward radial force of theexpandable tissue-engaging ring 1450 against the tissue and supported bythe anchoring members 110 and/or 1410 can prevent the device 1400 frommigrating in an upstream direction. Additionally, the expandabletissue-engaging ring 1450 along with at least the portions of theanchoring members 110 and/or 1410 that are uncoupled from the valvesupport 120 can effectively mechanically isolate the valve support 120and the valve 130 from compromising radially compressive forces exertedon the device 1400 from the heart valve tissue.

FIG. 70 is a cross-sectional side view of another prosthetic heart valvedevice 1500 configured in accordance with an embodiment of the presenttechnology. The device 1500 can also include features as described aboveincluding a valve support 120 and a prosthetic valve 130 retained withinthe valve support 120. The device 1500 can also include a plurality ofanchoring members (individually identified as 110 a-c). The anchoringmembers 110 a-c can be coupled at respective downstream perimeters 115a-c to the valve support 120 and be separated by gaps 1515 such thatrespective upstream perimeter 113 a-c can engage cardiac tissue atvariable target locations at the native valve. Optionally, the device1500 can also include the expandable tissue-engaging ring 1450 (FIGS.69A-D) such as those having tissue engaging features 170 for furtherengaging tissue at the native valve. In one embodiment, the expandabletissue-engaging ring 1450 can be coupled to the upstream perimeter ofmore than one anchoring member (e.g., the upstream perimeters 113 b and113 c of anchoring members 110 b and 110 c). However, in otherarrangements, the device 1500 will not have the expandabletissue-engaging ring 1450.

FIG. 71 is a cross-sectional side view of yet another prosthetic heartvalve device 1600 configured in accordance with an embodiment of thepresent technology. The device 1600 can also include features asdescribed above including a valve support 120 and a prosthetic valve 130retained within the valve support 120. The device 1500 can also includethe anchoring member 110. However, the device 1600 can also include anexpandable retainer 1610 for further engaging tissue at or near thenative valve annulus. In one embodiment, the retainer 1610 can be anextension of upstream end 121 of the valve support 120, however, inanother embodiment, the retainer 1610 can include a separate expandablefeature coupled to the upstream end 121 of the valve support. In somearrangements, the retainer 1610 can be mechanically isolated from thevalve support 120 such that forces generated at the native valve areabsorbed or otherwise translated by the retainer 1610. In this manner,the retainer 1610 may be deformed by radial forces exerted on theretainer 1610 while the valve support remains substantially undeformed.

In one embodiment, as shown, the anchoring member 110 can be configuredto engage the retainer 1610; however, in other embodiments, theanchoring member 110 can be positioned differently such that theanchoring member 110 contacts tissue different than that of the retainer1610. For example, the anchoring member 110 may extend outside a radius(not shown) of the retainer to contact subannular tissue. Additionaldetails and embodiments regarding the structure, delivery and attachmentof retainers 1610 suitable for use with the prosthetic heart valvedevices disclosed herein can be found in International PCT PatentApplication No. PCT/US2012/61215, (Attorney Docket NO. 82829-8005WO00),entitled “DEVICES, SYSTEMS AND METHODS FOR HEART VALVE REPLACEMENT,”filed Oct. 19, 2012, the entire contents of which are incorporatedherein by reference.

FIG. 72 is an isometric view of a prosthetic heart valve device 1700 inaccordance with another embodiment of the present technology. The device1700 can include an anchoring member 110, a valve support 120 positionedradially within at least a portion of the anchoring member 110, and aprosthetic valve 130 retained within the valve support 120. The device1700 can further include a first sealing member portion 140 a coupled toan inner wall of the anchoring member 110 and a second sealing portion140 b coupled to the inner wall of the valve support 120. In otherembodiments, the first sealing member portion 140 a can be coupled tothe outer wall of the anchoring member 110 and/or the second sealingmember portion 140 b can be coupled to the outer wall of the valvesupport 120. The first and second sealing member portions 140 a and 140b can be integral portions of a single sealing member, or the first andsecond sealing member portions 140 a and 140 b can be separate sealingmembers that are attached independently to the anchoring member 110 andthe valve support 120. The first and second sealing member portions 140a and 140 b will in any event together form a sealed barrier between thevalve support 120 and the anchoring member 110 to inhibit or preventblood from flowing outside of the valve support 120 as blood flows fromthe atrium to ventricle or vice versa. As with several embodimentsdescribed above, an upstream portion 121 of the valve support 120 isspaced radially inward from the anchoring member 110, and a downstreamportion 123 of the valve support 120 is coupled to the anchoring member110.

FIG. 73 is a side view of the prosthetic heart valve device 1700, andFIG. 74 is a bottom isometric view of the prosthetic heart valve device1700. The anchoring member 110 can include a fixation portion 1710configured to securely fix the anchoring member 110 to tissue at anative heart valve, an integration region 1720 configured to integratethe anchoring member 110 with the valve support 120, and a lateralportion 1730 between the fixation portion 1710 and the integrationregion 1720. The fixation portion 1710, integration region 1720, andlateral portion 1730 can be formed by a plurality of structural elements1711 that can extend from the fixation portion 1710 to the integrationregion 1720. The integration region 1720 and the lateral region 1730 cancollectively or individually define a connection structure thatpositions and controls the fixation portion 1710 relative to the valvesupport 120. The structural elements 1711 can be shaped and connected toform diamond-shaped or other structural configurations that provide thedesired strength and flexion. The structural elements 1711 can be strutsor other structural features formed from metal, polymers, or othersuitable materials that can self-expand or be expanded by a balloon orother mechanical expander.

Several embodiments of the fixation portion 1710 can be a generallycylindrical fixation ring having an outwardly facing engagement surface1712, which may be a large, generally cylindrical surface for engagingtissue at or near the annulus of a native valve. For example, the outersurface of the fixation portion 1710 can extend in a direction P-P thatis at least substantially parallel to a longitudinal axis L-L, or thefixation portion 1710 can be inclined to converge from the lateralportion 1730 toward the longitudinal axis L-L such that all or a portionof the fixation ring is tapered in the upstream direction. For example,the fixation portion 1710 can be inclined inwardly (arrow I) toward thelongitudinal axis L-L in the upstream direction at an angle of 0 to −30°relative to the longitudinal axis L-L In other embodiments, the fixationportion 1710 can be inclined outwardly (arrow O) from the longitudinalaxis L-L by an angle of 0 to 45° to increase the outward radial force.In several embodiments, the fixation portion 1710 can be parallel to anoutwardly facing surface of the valve support 120.

Several embodiments of the anchoring member 110 are configured to pressthe engagement surface 1712 against tissue at an implant site on orbelow a native annulus of the native heart valve when the orientation ofthe fixation portion 1710 is at least generally parallel to thelongitudinal axis L-L or tapered inwardly in the upstream direction. Thefixation portion 1710 may have such a configuration in an unbiased statebefore implantation, or it may assume this inwardly taperedconfiguration through deformation imposed by engagement with tissue atthe implant site. For example, the fixation portion 1710 can bedeflectable through a range of angles relative to the longitudinal axisL-L such that upon engagement with the tissue the fixation portion 1710moves from an unbiased state to the implanted orientation in which it isorientated at least substantially parallel to or tapered in the upstreamdirection toward the longitudinal axis L-L. As explained in more detailbelow, the large, generally cylindrical area of the outer surface of thefixation portion 1710 and the orientation of the fixation portion 1710in a direction P-P provide good fixation to the annulus and subannulartissue of a native mitral valve or other heart valve. In severalembodiments, the fixation portion can have a height (H) of 10 mm-20 mm.

The fixation portion 1710 of the anchoring member 110 may have differentregions of radial stiffness along the P-P axis. These regions canconform to and exert an outward radial force on the surrounding anatomyto provide fixation and sealing. In one example, the radial stiffnessmay be greater in the region of the fixation portion that is downstreamof the annulus and lesser in the region that is in contact with andupstream of the annulus. This combination would provide a regiondownstream of the annulus that resists compression and ensures that thedevice maintains its fixation with respect to the anatomy when subjectedto a systolic pressure gradient and a region at the annulus that allowssome compression (preventing dilation of the annulus), but maintainssufficient radial outward force to keep the fixation portion in contactwith the anatomy to provide sealing between the device and the anatomy.

Radial stiffness may be controlled by the design of the structuralelements of the attachment portion 1720 and/or the lateral portion 1730,the taper angle or curve between these regions and the fixation portion1710, or a combination of those properties. The design of the structuralelements 1711 of the fixation portion 1710 may have different properties(wall thickness, width, length, angle, etc.) along with the P-P axis toprovide regions of different radial stiffness. Additionally, thefixation portion 1710 can have a first flexibility and the integrationregion 1720 and/or the lateral portion 1730 can have a secondflexibility different than the first flexibility. The fixation portion1710 can itself have a downstream region with a first flexibility and anupstream region with a second flexibility different than the firstflexibility.

The fixation portion 1710 can further include a plurality of tissueengaging elements 170 configured to penetrate into the annulus and/orsubannular tissue. The prosthetic heart valve device is preferablyanchored solely by the engagement of fixation portion 1710 with thenative tissue, which resists the high forces of blood against the deviceduring ventricular systole. Other means of anchoring, such astissue-engaging arms or tethers coupled to the native tissue, are notrequired. Thus, the tissue engaging elements 170 are configured toengage the native tissue to reliably resist movement of the devicewithout fully penetrating or perforating the leaflets or heart walltissue, or otherwise causing undue trauma as the heart beats. Becausethe upstream forces during ventricular systole are so high, the tissueengaging elements 170 will preferably project at least in the upstreamdirection to inhibit movement of anchoring member 110 in the upstreamdirection relative to the native tissue. Smaller forces are exerted onthe device in the downstream direction during diastole, so in some casesdownstream-projecting tissue engaging elements may also be desirable(e.g., project superiorly in the case of a mitral valve). In oneembodiment, the fixation portion 1710 can include an upper row 171 a oftissue engaging elements that project superiorly and inferiorly, asecond row 171 b of tissue engaging elements that also extend superiorlyand inferiorly, and a third row 171 c of tissue engaging elements thatextend superiorly. The tissue engaging elements 170 can be barbs, tines,pins, or other elements that penetrate into or otherwise grip the tissueof the native annulus and/or native subannular tissue. In severalembodiments, the tissue engaging elements 170 project radially outwardfrom the structural elements 1711 of the fixation portion 1710 by adistance of approximately 0.5-5 millimeters.

The integration region 1720 of the anchoring member 110 can be formedfrom the lower portions of the structural elements 1711. In theembodiment illustrated in FIGS. 73 and 74, the integration region 1720has a plurality of diamond-shaped structures 1722 and vertical members1724. In the illustrated embodiment, each of the vertical members 1724can include a portion of two of the structural elements 1711. In severalembodiments, the anchoring member 110 and the valve support 120 are madefrom separate struts, and the integration region 1720 is an attachmentportion or fastening portion of the anchoring member 110 that isattached to the valve support 120. For example, when the anchoringmember 110 and the valve support 120 are separate components, theintegration region 1720 can be an attachment portion including aplurality of connecting points 1726 where the integration region 1720 iscoupled to the valve support 120. In one embodiment, the integrationregion 1720 of the anchoring member 110 can be connected to the valvesupport 120 at a plurality of connecting points 1726 (e.g., 12) usingNitinol rivets. In other embodiments, threads, adhesives, solder, laserwelding, metal bolts or other mechanical features, or other types offasteners can be used to secure the valve support 120 to the integrationregion 1720. The integration region 1720 can thus be a fasteningportion.

In other embodiments, the anchoring member 110 and the valve support 120are integrally formed together from common struts, or a number of strutscan be integrally formed with both the anchoring member 110 and thevalve support 120. In these embodiments, the integration region 1720 isthe structure that transitions from the anchoring member 110 to thevalve support 120 without otherwise being fastened together. Forexample, the integration region 1720 can be a curved or otherwise bentportion of such struts between a cylindrically shaped valve support 120and the portion of the anchoring member 110 that projects away from thevalve support 120.

The lateral portion 1730 extends between the upper region of theintegration region 1720 and the lower region of the fixation portion1710 in the embodiment shown in FIGS. 72-74. The lateral portion 1730,for example, extends laterally outward from the integration region 1720to the fixation portion 1710. In one embodiment, the lateral portion1720 includes a plurality of connectors 1732 having lateral sections1733 (FIG. 74) formed from a portion of the structural elements 1711.The lateral sections 1733 of the connectors 1732 extend laterally, whichin several embodiments is a direction transverse to the longitudinalaxis L-L in an outwardly straight, conical, curved, or outwardly angled(e.g., flared) configuration. Additionally, “traverse direction”includes any non-parallel direction relative to the longitudinal axisL-L. The connectors 1732 can have a first transition zone 1734 thatcurves from the orientation of the fixation portion 1710, which isgenerally parallel to or canted inwardly toward the longitudinal axisL-L, to the lateral sections 1733 of the connectors 1732 that aretransverse to the longitudinal axis LL. In many embodiments the lateralsections 1733 of the connectors 1732 are nearly perpendicular orperpendicular to the longitudinal axis L-L. The connectors 1732 can alsohave second transition zone 1736 that curves from the lateral sections1733 of the connectors 1732 to the orientation of the integration region1720 that extends at least generally parallel to the longitudinal axisL-L (FIG. 73). In the embodiment shown in FIG. 73, the first transitionzone 1734 is an inward and/or superior bend at an angle of approximately60°-160° (e.g., approximately 90°) from the lateral sections 1733 to theorientation of the engagement surface 1712 of the fixation portion 1710.The second transitional zone 1736 can be a downward and/or inferior bendat an angle in the range of 75°-160° (e.g., approximately 90°) from thelateral sections 1733 of the connectors 1732 to the integration region1720. The smaller angles result in an S-Shape; the larger angles resultin a tapered transition as shown in FIG. 75. The first transition zone1734 can thus be a concave curve with respect to the longitudinal axisL-L, and similarly the second transition zone 1736 can be a convex curvewith respect to the longitudinal axis L-L. The curves of the firsttransition zone 1734 and the second transitional zone 1736 enable thefixation portion 1710 to present a large engagement surface 1712 tocontact the annulus and leaflets of the native heart valve to providegood fixation of the device 1700. The connectors 1732 also enable thefixation portion 1710 to flex based on the shape of the native annulusand the contraction of the left ventricle without transmitting the fullforces of such flexure of the fixation portion 1710 to the upstreamportion 121 of the valve support 120 where the prosthetic valve 130 isattached. The device 1700 accordingly provides enhanced fixation to thenative tissue and sufficient mechanical isolation between the fixationportion 1710 and the upstream portion 121 of the valve support 120 suchthat the prosthetic leaves of the prosthetic valve 130 maintainsufficient contact with each other to inhibit backflow after theanchoring member 110 has been implanted at a native mitral valve andduring left ventricular contraction.

In several embodiments, as explained above, the integration region 1720and the lateral portion 1730 can individually or collectively define aconnecting structure that interconnects the anchoring member 110 andvalve support 120. The connecting structure can comprise a plurality ofstruts that each have an inner end connected to or integral with thevalve support 120 and an outer end connected to or integral with theanchoring member 110. For example, the connecting structure can be aflared portion that flares outwardly from the valve support 120 in theupstream direction, and in selected embodiments the connecting structurecan be configured to be disposed entirely downstream of the nativeannulus when the anchoring member is at the implant site. The connectingstructure can have an upstream end connected to the anchoring membersuch that the upstream end is positioned below the native annulus whenthe anchoring member is at the implant site.

The anchoring member 110 can thus include the fixation portion 1710 andthe connection structure 1720/1730, and the connection structure1720/1730 can have an inner end connected to the valve support 120, anouter end connected to the fixation portion 1710, and an intermediateportion between the inner end and the outer end which flares outwardlyfrom the valve support 120. The intermediate portion, for example, canflare outwardly in an upstream direction.

The fixation portion 1710 can have a skirt covering an inward-facingsurface of the fixation portion 1710, and in additional embodiments theskirt can further cover an inward-facing side of the connectingstructure. Additionally, the device 1700 can further include a tubularvalve cover extending around the valve support, and the skirt can beattached to the tubular valve cover. In additional embodiments, thevalve cover is disposed on an inward facing surface of the valvesupport.

FIG. 75 is a side view of another embodiment of the prosthetic heartvalve device 1700, and FIG. 76 is a bottom view of the prosthetic heartvalve device 1700 shown in FIG. 75. In this embodiment, the connectors1732 of the lateral portion 1730 are defined by laterally extendingportions of individual structural elements 1711 that extend between thefixation portion 1710 and the integration region 1720. Referring to FIG.76, each connector 1732 includes a single one of the structural elements1711 as opposed to two structural elements 1711 as shown in FIGS. 72-74.Additionally, the connectors 1732 are inclined at a non-perpendicularangle with respect to the longitudinal axis L-L of the device 1700. Theconnectors 1732 nonetheless each include a first transition 1734 bendingfrom the connectors 1732 to the fixation portion 1710, and a secondtransition zone 1736 bending from the connectors 1732 to the integrationregion 1720.

FIG. 77 is a side view of the prosthetic heart valve device 1700 inaccordance with another embodiment of the present technology. In thisembodiment, the device 1700 wraps a portion of the first sealing memberportion 140 a around a rim 1714 of the fixation portion 1710 of theanchoring member 110. The section of the first sealing portion 140 awrapped over the rim 1714 provides an atraumatic edge to protect theroof of the left atrium during implantation and use.

FIG. 78 is an isometric view of the prosthetic heart valve device 1700in accordance with yet another embodiment of the present technology. Inthis embodiment, the material of the second sealing portion 140 b on theinside of the valve stent 120 has openings 142 a-142 c spaced apart fromeach other around the perimeter of the valve support 120. The openings142 a-142 c are spaced between the commissures where the prostheticvalve 130 is attached to the second sealing portion 140 b. In operation,the open areas 142 a-142 c are expected to decrease static blood volumeon the atrial side of the device 1700 to reduce fibrin and thrombusdeposition and to provide better flow dynamics.

FIGS. 79A and 79B are partial cross-sectional views of a heart (H) andside views of an embodiment of the prosthetic heart valve device 1700showing an embodiment of a method for implanting the prosthetic heartvalve device 1700 in accordance with the present technology. Referringto FIG. 79A, the device 1700 is attached to a delivery device 1800(shown schematically) and inserted into the heart (H) via a transapicalapproach in a low-profile configuration (not shown). The device 1700 isinserted superiorly (arrow S) through the native mitral valve (MV). Thefixation portion 1710 of the device 1700 can be positioned in the leftatrium (LA) at this stage of the procedure, and then relative movementbetween an outer member 1810 and an inner member 1820 of the deliverydevice 1800 can release the fixation portion 1710 from the deliverydevice 1800. The fixation portion 1710 can then self-expand or beexpanded using a balloon or other mechanical expander to a partiallydeployed state in which the integration region 1720 remains attached tothe delivery device 1800. In the partially deployed state shown in FIG.79A, the fixation portion can have a diameter that is larger than theopening defined by the annulus (AN) of the mitral valve (MV). Inselected embodiments, the outer diameter of the fixation portion 1710 ofthe device 1700 can be between approximately 38 mm and 56 mm dependingon the size and shape of the native annulus (AN) of the mitral valve(MV). It will be appreciated that other sizes can be used depending onthe specific anatomy of a patient.

FIG. 79B illustrates the prosthetic heart valve device 1700 after it hasbeen positioned at a desired location with respect to the annulus (AN)of the native mitral valve (MV). The device 1700 reaches the positionshown in FIG. 798 by moving the delivery device 1800 (FIG. 79A)inferiorly (arrow W) until the fixation portion 1710 contacts andfixedly engages the annulus (AN). In some embodiments, the rim 1714 ofthe fixation portion 1710 can project slightly superior of the annulus(AN). The rim 1714 can accordingly be positioned approximately 1-5 mmabove the native annulus (AN) at the anterior leaflet (AL) side of theatrium (LA) in such embodiments. In other embodiments, the rim 1714 ofthe fixation portion 1710 can be positioned at or below the upper rim ofthe annulus (AN) such that the fixation portion 1710 contacts at leastthe annulus (AN) and potentially a portion of the anterior leaflet (AL)and/or the posterior leaflet (PL) of the mitral valve (ML). In stillother embodiments, the rim 1714 of the fixation portion 1710 can bepositioned at a subannular (SA) location underneath the annulus (AN)(not shown in FIG. 79B). After the device 1700 is positioned at adesired location relative to the annulus (AN) of the mitral valve (MV),the delivery device 1800 (FIG. 79A) is withdrawn inferiorly (arrow W inFIG. 79A) and removed from the patient.

In the embodiment shown in FIG. 79B, the device 1700 is implanted suchthat the rim 1714 is approximately 1-5 mm above the native annulus (AN).Since the diameter of the fixation portion 1710 in the expandedconfiguration is greater than that of the native annulus (AN), the outersurface of the fixation portion 1710 and the tissue engaging members 170securely hold the anchoring member 110 with respect to the mitral valve(MV).

FIG. 79C is an anatomical cross-section view of a heart (H) showing thedevice 1700 implanted at a location slightly lower than the positionshown in FIG. 79B such that the rim 1714 of the fixation portion 1710pushes outward under a portion (AN1) of the native annulus (AN). Thedevice 1700 can also be implanted lower than the elevation shown in FIG.79C. For example, the rim 1714 of the fixation portion 1710 can bepositioned at an elevation E-E at the bottom of the annulus (AN) or evenat the subannular space (SA). In all of these embodiments, the portionof the native annulus (AN) over the rim 1714 further restricts thedevice 1700 from moving upwardly into the left atrium (LA) duringventricular systole.

FIG. 79D is a schematic view showing an aspect of implanting the device1700 as shown above in FIG. 79B or 79C, or in many other applications aswell. Referring to FIG. 79D, the outwardly-projecting portion of theanchoring member 110 that extends from the valve support 120 to thefixation portion 1710, which can be the laterally curved connectionstructure 1730 a in FIG. 79D, is preferably located entirely downstreamof the native annulus (AN) as shown in FIGS. 79B and 79C. For example,the transition zone 1734 between the connecting structure 1730 a and thefixation portion 1710 can be located inferiorly of the lower portion(LMV) of the mitral valve annulus (AN) to urge or drive the downstreamend of fixation portion 1710 outwardly below the annulus (AN). Thisallows the anchoring member 110 to engage tissue on the downstreamsurface of the native annulus so that that upstream forces against theprosthetic device 1700 during ventricular systole are resisted by boththe resulting upward force against the annulus (AN) as well as theoutward pressure of the fixation portion 1710 against the annulus (AN),friction between the fixation portion 1710 and the annulus (AN), and theengagement of tissue engaging elements 170 with the native tissue.

The anchoring member 110 and the valve support 120 can be configuredsuch that the downstream end of the valve support 120 is disposed notmore than 26 mm downstream of the native annulus (AN). Additionally, thefixation portion 1710 can be configured such that the engagement surfacehas a width (e.g., height) of at least about 10-20 mm. The connectingstructure can additionally have a height (H_(j) in FIG. 73) of not morethan about 0-15 mm downstream from the end at the valve support 120 tothe outer end at the fixation portion 1710. The total height (H_(t) FIG.73) of the device 1700 can be approximately 16-26 mm.

The large contact area of the engagement surface 1712 (FIG. 73) thatfaces the tissue located at or near the annulus (AN) providesexceptionally good fixation to hold the device 1700 at a desiredlocation, and the tissue engaging elements 170 around the fixationportion 1710 further enhance the fixation of the device 1700 to theregion of the annulus (AN). The transverse orientation of the connectors1732 further provides significant outward support of the fixationportion 1710 to exert a sufficient outward force against the annulus(AN), yet the orientation and configuration of the connectors 1732 incombination with attaching the valve support (not shown in FIG. 79B) tothe terminus of the integration region 1720 isolates the upstreamportion of the valve support from forces exerted by the fixation portion1710 to accommodate for the irregular shapes and motion of the mitralvalve (MV) after implantation. Also, as noted above, the anchoringmember further secures the device 1700 to the anatomy by compressingupwardly against the bottom or lower portion of the native annulus (AN)in combination with the friction and radial hoop force exerted by thefixation portion 1710 and the tissue engaging elements as describedabove with reference to FIGS. 79B-79D. Tests of the device 1700 furthershow that tissue grows in and around the fixation portion 1710, whichfurther secures the device 1700 to the desired location relative to theannulus (AN).

FIGS. 80A-80K are schematic cross-sectional views of several additionalembodiments of prosthetic heart valve devices 1700 in accordance withthe present technology. Like reference numbers refer to similar oridentical components in FIGS. 72-80K. The embodiment of the device 1700illustrated in FIG. 80A represents several of the embodiments describedabove with reference to FIGS. 72-79D. In this embodiment, the supports1732 extend at an angle α of 30°-90° with respect to the longitudinaldimension L-L of the device 1700. As the angle α approaches 90 degrees,the loads from the fixation portion 1710 to the valve support 120increase relative to angles that are less than 90 degrees. As such, agreater taper (e.g., lower angle α) reduces the loads transmitted to thevalve support 120 and the prosthetic valve 130.

FIG. 80B illustrates an embodiment of the device 1700 in which theconnectors 1732 have an S-shape. One advantage of having S-shapedconnectors 1732 is that the valve support 120 can be shortened tomitigate the extent that the device 1700 protrudes into the leftventricle and interrupts flow through the LVOT. As noted above, thelower end of the device 1700 can interfere with the flow through theLVOT during ventricular contraction.

FIG. 80C illustrates an embodiment of the device 1700 in which theanchoring member 110 is inverted such that the fixation portion 1710 islocated around the downstream portion 123 of the valve support 120 andthe integration region 1720 is attached to the upstream portion of thevalve support 120. This embodiment of the device 1700 positions thevalve support 120 further into the left atrium as opposed to the leftventricle.

FIG. 80D illustrates an embodiment of the device 1700 in which thefixation portion 1710 is orientated downwardly to be positioned at theelevation of the downstream portion of the valve support 1720. Thisembodiment is expected to inhibit loads from being transmitted from thefixation portion 1710 to the valve support 120, and it also positionsthe valve support 120 to reduce the valve support 120 from protrudinginto the left ventricle.

FIG. 80E illustrates an embodiment of the device 1700 in which the valvesupport 120 is offset relative to different areas of the fixationportion 1710. In this device, the anchoring member 110 can include firstconnectors 1732 a between the fixation portion 1710 and the valvesupport 120 at one side of the device 1700, and second connectors 1732 bbetween the valve support 120 and the fixation portion 1710 at anotherside of the device 1700. The first connectors 1732 a can be shorter thanthe second connectors 1732 b such that the valve support 120 is closerto the fixation portion 1710 at the one side of the device compared toanother side of the device. The embodiment of the device 1700illustrated in FIG. 80E may advantageously position the valve support120 and prosthetic valve 130 further away from the LVOT to mitigateinterference with blood flow during ventricular contraction.Additionally, the embodiment of the device 1700 shown in FIG. 80E isexpected to provide a more uniform load distribution to accommodate forthe non-circular shape and saddle profile of the mitral valve annulus.

FIG. 80F illustrates an embodiment of the device 1700 in which theintegration region 1720 of the anchoring member 110 is attached to anintermediate portion of the valve support 120 as opposed to the end ofthe valve support 120. The embodiment of the device 1700 illustrated inFIG. 80F may reduce the interaction between the fixation portion 1710and valve function.

FIG. 80G illustrates another embodiment of the device 1700 in which thevalve support 120 has commissural attachment structures 128 that haveextensions 1728 that project radially inwardly from the downstream endof the commissural attachment structures. The extensions 1728 canconverge inwardly at a desired angle toward the central axis of thedevice 1700. In one embodiment, the angle of the extensions 1728maintains an appropriate minimum required bend radius so that theextensions 1728 can be linearized to minimize valve diameter duringplacement. The integration region 1720 of the anchoring member 110 canbe attached to the extensions 1728. The embodiment of the device 1700illustrated in FIG. 80G is expected to increase the minimum requiredbend radius for the connectors 1732, and reduce the height of thefixation portion 1710 for a given taper angle. The inward extensions1728 might also provide an advantageous attachment point for thecommissures of the valve tissue. By moving this attachment point furtherinto the ventricle and further towards the centerline of the valve, theoverall stresses on the valve tissue will be reduced. If the free edgesof the valve leaflets are slightly shorter than the commissures, theywill not touch these extensions 1728 in the open position. Thereforeblood flow will not be impeded, and the leaflets will not be damaged byrepeatedly touching the extensions.

FIG. 80H is a cross-sectional view of another embodiment of theprosthetic heart valve 1700 in accordance with the present technology.In this embodiment, the lateral portion 1730 has a continuouslyoutwardly flared shape from the downstream end 123 of the valve support120, and the integration region 1720 is at the terminus of the lateralportion 1730 where the anchoring member 110 is attached to the valvesupport 120. The first transition zone 1732 of the lateral portion 1730bends superiorly from the lateral portion 1730 to the orientation of thefixation portion 1710 such that the fixation portion 1710 is configuredto face the tissue of a native mitral valve. This embodiment thus showsa flared laterally extending lateral portion 1730.

FIG. 80I is a cross-sectional view of another embodiment of theprosthetic heart valve 1700 in accordance with the present technology.In this embodiment, the lateral portion 1730 has an outwardly projectingconical shape from the downstream end 123 of the valve support 120, andthe integration region 1720 is at the terminus of the lateral portion1730 where the anchoring member 110 is attached to the valve support120. The first transition zone 1732 of the lateral portion 1730 bendssuperiorly from the lateral portion 1730 to the orientation of thefixation portion 1710 such that the fixation portion 1710 is configuredto face the tissue of a native mitral valve. This embodiment thus showsa conical laterally extending lateral portion 1730.

FIG. 80J is a cross-sectional view of another embodiment of theprosthetic heart valve 1700 in accordance with the present technology.In this embodiment, the lateral portion 1730 has arms that are slightlyconvex when viewed from the downstream end, or concave when viewed fromthe upstream end. In this embodiment, the systolic blood pressureagainst the valve and valve support imparts a compressive column loadingon each of the arms. Due to the slightly bent shape of the arms, thisimparts a slight bending load on the arms in the downstream direction.At the same time, the systolic blood pressure against the armsthemselves and the attached sealing portions imparts a slight bendingload on the arms in the upstream direction. By optimizing the curvatureof the arms, the net bending load on the arms due to blood pressure canbe minimized or eliminated.

FIG. 80K is an isometric view of another embodiment of the prostheticheart valve device 1700 in accordance with the present technology. Inthis embodiment, the fixation portion 1710 includes an extension 1713that extends downstream from the first transition zone 1734. Theextension 1713 can be formed by extensions of selected structuralelements 1711 that project downstream beyond the area where thetransition zone 1734 comes into the fixation portion 1710. The extension1713 increases the height of the fixation portion 1710, and it furtherenhances sealing and ingrowth at the downstream portion of the fixationportion 1710. For example, the extension 1713 can enhance the ingrowthat the ventricular portion of the fixation portion 1710 of a mitralvalve device.

FIG. 81A is a cross-sectional view schematically showing a prostheticheart valve device 1900 in accordance with another embodiment of thepresent technology. The device 1900 can include an anchoring member 110,valve support 120, and prosthetic valve 130. The device 1900 can furtherinclude a compartment 1910 attached to one or both of the anchoringmember 110 and the valve support 120. The compartment 1910 can beconfigured to fit between the anchoring member 110 and the valve support120. The compartment 1920 can extend around only a portion of thecircumference of the anchoring member 110, or the compartment 1910 canextend around the entire inner circumference of the anchoring member110. The compartment 1910 can further include a second portion 1910 athat projects towards the left atrium to provide more space for packinginto a low-profile configuration.

In one embodiment, the compartment 1910 is made from a fabric, mesh,braid, porous material, or other suitable material that can contain amaterial 1920. The fabric, mesh, or other material might be optimized onone end to minimize blood flow through it during the initial periodafter implantation, while the other end might be more open to allow moreaggressive tissue ingrowth and even vascularization of the compartment1910. The material 1920, for example, can be a time-released agent thatinhibits or prevents clotting (e.g., clopidogrel or aspirin), a healingagent (ascorbic acid), or other agents that promote tissue and growth.The material 1920 can alternatively include structural filler elements,such as small spheres, random intermeshed fibers, foam, swellablehydrogels, etc., either in lieu of or in addition to anti-clotting andhealing agents. These small spheres, fiber, foam etc. might be optimizedfor their compressibility. In this way the structural filler elementscan provide structural support between the anchoring member 110 and thevalve support 120 without transmitting fully forces from the anchoringmember 110 to the valve support 120. The compartment 1910 can beattached to the anchoring member 110 or the valve support 120 byfasteners 1930, such as clasps, threaded ties, or other suitablefasteners. The material 1920 might be introduced into the device afterthe device has been deployed into the patient, for example via a tubewhich extends from the compartment 1910 to the proximal end of thedelivery system. Once the compartment 1910 has been filled with material1920, the tube can be pulled out of compartment 1910, with aself-sealing valve preventing leakage of material 1920 from thecompartment.

FIG. 81B is a top view of the prosthetic heart valve device 1900illustrating an embodiment in which the compartment 1910 has a pluralityof separate cells 1912 (identified individually as cells 1912 a-1912 g).Each of the cells 1912 can include the same material 1920 (FIG. 81A), ora number of the cells can include different materials 1920. For example,cells 1912 a, 1912 c, 1912 c, and 1912 g can include an anticlottingagent, and cells 1912 b, 1912 d, and 1912 f can include a healing agentto promote healing of connective tissues.

FIG. 82A is an isometric view of a prosthetic heart valve device 2000 inaccordance with another embodiment of the present technology, and FIG.82B is a cross-sectional view of the device 2000 along line 20B-20B inFIG. 20A. The device 2000 can include an anchoring member 110 having aframe and a plurality of tissue engaging elements 170 similar to thefixation portion 1710 of the devices 1700 described above. The device2000 can further include one or more fibers or webs 2010 that flexiblycouple the anchoring member 110 to the valve support 120. The webs 2010,for example, can be a fabric, mesh, braid, sheet, or other materialformed form a textile, polymer, metal, natural fiber, or other suitablematerials. These webs might have a variety of orientations.

Referring to FIG. 82B, the web 2010 can include a first portion 2012 atthe upstream end of the valve support 120, a second portion 2014 at thedownstream end of the valve support 120, and side portions 2016 attachedto the anchoring member 110 and the valve support 120 by fasteners 2020.The web 2010 illustrated in FIG. 82B can form an enclosed compartment2018 that can be filled with a material such as a time-release agentand/or filler elements as described above. The fasteners 2020 can besutures, other threaded ties, clasps, rivets or other suitable fasteningmeans. Additional fibers or webs might extend from the downstream end ofthe anchoring member to the upstream end of the valve support, from theupstream end of the anchoring member to the downstream end of the valvesupport, or in other directions. Alternatively, verticalradially-oriented planar webs may extend from the anchoring member tothe valve support.

The device 2000 illustrated in FIGS. 82A and 82B may provide very goodforce isolation between the anchoring member 110 and the valve support120 because there is no metal-to-metal interface and the suture-typefasteners 2020 add further stability and potentially better fatiguelife. The device 2000 has the potential for further improving fatiguelife because of the robust materials that can be used for the web 2010(e.g., Kevlar®, a trademark of E. I. du Pont de Nemours and Company) andthe flexibility of the web 2010.

FIG. 83 is a schematic cross-sectional view of the device 2000 inaccordance with another embodiment of the present technology. In thisembodiment, the web 2010 has a top portion between the upstream ends ofthe anchoring member 110 and the valve support 120, and the sideportions are connected to the anchoring member 110 and the valve support120 by fasteners 2020. The device 2000 in this embodiment furtherincludes tethers 2040 attached to the downstream end of the anchoringmember 110 and to an intermediate area of the valve support 120.

FIGS. 84A-84C are schematic cross-sectional views illustrating an aspectof several embodiments of the prosthetic heart valve devices 1700, 1900and 2000 in accordance with the present technology. Referring to FIG.84A, the device 1700 can have a fully expanded state in which thefixation portion 1710 extends from the lateral portion 1730 (e.g.,connecting structure) by an angel of 45° outwardly away from thelongitudinal axis of the device 1700 to an angle of −30° inwardly towardthe longitudinal axis of the device. The fixation portion 1710 extendsapproximately parallel to the longitudinal axis of the device in theembodiment shown in FIG. 84A. The device 1700 can have such a fullyexpanded state outside of the body or after the device 1700 has beenimplanted at a native valve. The fixation portion 1710, however, canflex or otherwise deform upon implantation such that the fixationportion 1710 at least partially adapts to the shape of the native valvelocation and deflects (arrow D) inwardly or outwardly to also at leastpartially adapt to the angular orientation of tissue at the native valvelocation. FIG. 84B, for example, shows deflection of the fixationportion 1710 inwardly to adapt to the angle of the tissue at theunderside of the native annulus (AN), and FIG. 84C shows deflection ofthe fixation portion 1710 outwardly to adapt to the angle of the tissueon the other side of the native annulus (AN). Such double conformabilityenhances the fixation of the device to the native tissue. Additionally,the fixation portion 1710 need not deflect with respect to the lateralportion 1730 at a mid-section of the fixation portion 1710 as shown insolid lines in FIG. 84A, but rather the fixation portion 1710 candeflect around areas that are at or near the ends of the fixationportion as shown by the transition areas of lateral sections 1730′ and1730″ shown in broken lines in FIG. 84A.

FIGS. 85A-85C are side views illustrating selected embodiments of thedeflection of the fixation portion 1710 relative to the lateral portion1730. Referring to FIG. 85A, the fixation portion 1710 can be connectedto the outer end of the lateral portion 1730 by a hinge 1737. In theembodiment shown in FIG. 85B, the fixation portion 1710 deflects aboutthe first transition zone 1734 where the lateral portion 1730 bends tothe fixation portion 1710. FIG. 85C shows an embodiment in which thefixation portion 1710 is attached to the lateral portion 1730 bymechanical fasteners 1738, such as pins, bolts, rivets, or otherfasteners. In any of these embodiments, the fixation member can pivot,rotate, flex or otherwise deflect to an inward orientation 1710′ or toan outward orientation 1710″ depending on the tissue at the implantsite.

Additional Embodiments

Features of the prosthetic heart valve device components described aboveand illustrated in FIGS. 10A-85C can be modified to form additionalembodiments configured in accordance with the present technology. Forexample, the prosthetic heart valve device 1100 illustrated in FIGS.65A-65B without flared anchoring members can include anchoring membersthat are coupled to the valve support or other feature and areconfigured to extend radially outward to engage subannular tissue.Similarly, the prosthetic heart valve devices described above andillustrated in FIGS. 57A-71 can include features such as sealing membersas well as stabilizing features such as arms and tissue engagingelements.

Features of the prosthetic heart valve device components described abovealso can be interchanged to form additional embodiments of the presenttechnology. For example, the anchoring member 1210 of the prostheticheart valve device 1200 illustrated in FIG. 67A can be incorporated intothe prosthetic heart valve device 600 shown in FIGS. 57A-57C.Additionally, many features of the prosthetic heart valve devices 1700,1900 and 2000 described above with reference to FIGS. 72-85C can be usedwith the prosthetic heart valve devices described above with referenceto FIGS. 10-71A, and vice versa.

The following Examples are illustrative of several embodiments of thepresent technology.

Examples

1. A prosthetic heart valve device, comprising:

-   -   a valve support having an upstream region and a downstream        region relative to blood flow through a native heart valve of a        human heart, the upstream region being configured to support a        prosthetic valve, the prosthetic valve having a plurality of        leaflets and having an undeformed shape in which the leaflets        coapt sufficiently to prevent backflow through the prosthetic        valve;    -   an anchoring member having a longitudinal dimension and        including a tissue fixation portion, an integration region        coupled to the valve support, and a plurality of lateral        connectors between the tissue fixation portion and the        integration region, wherein the tissue fixation portion is        configured to (a) engage tissue at an implant site located at        and/or downstream of a native annulus of the native heart valve        and (b) be at least partially deformable into a non-circular        shape to adapt to a shape of the tissue at the implant site in a        deployed state, and wherein the lateral connectors have a        lateral section extending in a transverse direction relative to        the longitudinal dimension of the anchoring member and at least        a first transition zone that bends in a direction different than        the transverse direction such that the tissue fixation portion        faces the tissue at the implant site in the deployed state; and    -   wherein the tissue fixation portion of the anchoring member is        mechanically isolated from the upstream region of the valve        support such that the upstream region of the valve support        maintains the undeformed shape if the anchoring member has        deformed in the non-circular shape.

2. A prosthetic heart valve device, comprising:

-   -   an anchoring member having a longitudinal dimension and        including a tissue fixation portion having a first        cross-sectional dimension in a deployed state, an integration        region having a second cross-sectional dimension in the deployed        state less than the first cross-sectional dimension, and a        lateral portion between the tissue fixation portion and the        integration region, wherein—        -   the tissue fixation portion is configured to (a) engage            tissue located at and/or downstream of a native annulus of a            heart valve in a human and (b) be at least partially            deformable into a non-circular shape to adapt to a shape of            the tissue engaged by the tissue fixation portion in a            deployed state, and        -   the lateral portion extends in a direction transverse with            respect to the longitudinal dimension of the anchoring            member and has at least a first transition zone that bends            from the transverse direction to the tissue fixation portion            such that the tissue fixation portion is configured to face            the native annulus in the deployed state; and    -   a valve support having a first region and a second region, the        first region having a cross-sectional shape in the deployed        state configured to support a prosthetic valve such that        prosthetic leaflets of the prosthetic valve contact each other        in the deployed state, and the second region of the valve        support being coupled to the fixation portion of the anchoring        member.

3. The prosthetic heart valve device of any of examples 1-2, wherein theconnectors or lateral portion further include a second transition zonethat bends from the lateral section or lateral portion to theintegration region.

4. The prosthetic heart valve device of any of examples 1-3, wherein theanchoring member has a first end at the tissue fixation portion and asecond end at the integration region, and wherein the first transitionzone bends from the lateral section or lateral portion toward the firstend of the anchoring member and second transition zone bends from thelateral section or lateral portion toward the second end of theanchoring member.

5. The prosthetic heart valve device of any of examples 1-4, wherein theconnectors or lateral portion further include a second transition zone,and wherein the first transition zone bends superiorly and the secondtransition zone bends inferiorly relative to the heart.

6. The prosthetic heart valve device of any of examples 1-5, wherein thefirst transition zone has a concave curvature with respect to thelongitudinal dimension of the anchoring member.

7. The prosthetic heart valve device of example 6, wherein theconnectors further comprise a second transition zone that bends from thelateral section or lateral portion to the integration region, andwherein the second transition zone has a convex curvature with respectto the longitudinal dimension of the anchoring member.

8. The prosthetic heart valve device of any of examples 1-7, wherein thetissue fixation portion extends at least substantially parallel to thelongitudinal dimension of the anchoring member.

9. The prosthetic heart valve device of any of examples 1-8 wherein thelongitudinal dimension is a central longitudinal axis of the anchoringmember, and the tissue fixation portion extends at angle inclinedinwardly toward the central longitudinal axis.

10. The prosthetic heart valve device of any of examples 1-9, whereinthe tissue fixation portion comprises a ring having right cylindricalshape and a plurality of barbs projecting from the ring.

11. The prosthetic heart valve device of any of examples 1-10, whereinthe tissue fixation portion has a height of 10-20 mm and a generallyflat outer surface along the height.

12. The prosthetic heart valve device of any of examples 1-11, whereinthe anchoring member has a first end at the tissue fixation portion anda second end at the integration region, and the second end of theanchoring member is connected to the downstream region of the valvesupport.

13. The prosthetic heart valve device of any of examples 1-11, whereinthe anchoring member has a first end at the tissue fixation portion anda second end at the integration region, and the second end of theanchoring member is connected to the upstream region of the valvesupport.

14. The prosthetic heart valve device of any of examples 1-13, furthercomprising a compartment between the anchoring member and the valvesupport, and a material in the compartment.

15. The prosthetic heart valve device of example 14, wherein thecompartment comprises a fabric container attached to the anchoringmember and/or the valve support, and the material includes at least oneof an anti-clotting agent and/or a healing agent.

16. The prosthetic heart valve device of any of examples 1-15, whereinthe lateral portion comprises an outwardly flared section, and thefixation portion extends at least substantially parallel to thelongitudinal dimension of the anchoring member.

17. The prosthetic heart valve device of any of examples 1-15, whereinthe lateral portion comprises an outwardly extending conical section,and the fixation portion extends at least substantially parallel to thelongitudinal dimension of the anchoring member.

18. A device for implantation at a native mitral valve, the nativemitral valve having a non-circular annulus and leaflets, comprising:

-   -   a valve support having a first region configured to be attached        to a prosthetic valve with a plurality of prosthetic leaflets        and a second region;    -   an anchoring member having a longitudinal dimension and        including a first portion configured to contact tissue at the        non-circular annulus and a second portion having a lateral        portion between the first portion and the valve support;    -   wherein the second portion of the anchoring member is attached        to the second region of the valve support while in a low-profile        configuration in which the anchoring member and the valve        support are configured to pass through vasculature of a human;    -   wherein the lateral portion is transverse to the longitudinal        dimension; and    -   wherein the anchoring member and the valve support are        configured to move from the low-profile configuration to an        expanded configuration in which the first portion of the        anchoring member at least partially adapts to the non-circular        annulus of the native mitral valve and the first region of the        valve support is spaced inwardly from the first portion of the        anchoring member relative to the longitudinal dimension of the        anchoring member such that a shape of the first region of the        valve support is at least partially independent of a shape of        the first portion of the anchoring member.

19. The device of example 18, wherein the first portion of the anchoringmember comprises a tissue fixation portion and the second portion of theanchoring member comprises an integration region.

20. The device of any of examples 18-19, wherein the lateral portioncomprises a plurality of lateral connectors, and individual connectorsinclude a lateral section extending in a transverse direction relativeto the longitudinal dimension of the anchoring member and at least afirst transition zone that bends in a direction different than thetransverse direction such that the first portion or the tissue fixationportion of the anchoring member faces tissue at the implant site in thedeployed state.

21. The device of any of examples 18-20, wherein the connectors orlateral portion further include a second transition zone that bends fromthe lateral section or lateral portion to the valve support.

22. The device of any of examples 18-21, wherein the first portion orthe tissue fixation portion of the anchoring member extends at leastsubstantially parallel to the longitudinal dimension of the anchoringmember.

23. The prosthetic heart valve device of any of examples 18-21 whereinthe longitudinal dimension is a central longitudinal axis of theanchoring member, and the first portion or the tissue fixation portionof the anchoring member extends at angle inclined inwardly toward thecentral longitudinal axis.

24. The prosthetic heart valve device of any of examples 18-23, whereinthe first portion or the tissue fixation portion of the anchoring membercomprises a ring having right cylindrical shape and a plurality of barbsprojecting from the ring.

25. The prosthetic heart valve device of any of examples 81-24, whereinthe anchoring member has a first end at the first portion or the tissuefixation portion and a second end at the second portion or theintegration region, and the second end of the anchoring member isconnected to a downstream region of the valve support.

26. The prosthetic heart valve device of any of examples 18.24, whereinthe anchoring member has a first end at the first portion or the tissuefixation portion and a second end at the second portion or theintegration region, and the second end of the anchoring member isconnected to an upstream region of the valve support.

27. The prosthetic heart valve device of any of examples 18-26, furthercomprising a compartment between the anchoring member and the valvesupport, and a material in the compartment.

28. The prosthetic heart valve device of any of examples 27, wherein thecompartment comprises a fabric container attached to the anchoringmember and/or the valve support, and the material includes at least oneof an anti-clotting agent and/or a healing agent.

29. The prosthetic heart valve device of any of examples 18-28, whereinthe lateral portion comprises an outwardly flared section, and the firstportion or the fixation portion of the anchoring member extends at leastsubstantially parallel to the longitudinal dimension of the anchoringmember.

30. The prosthetic heart valve device of any of examples 18-28, whereinthe lateral portion comprises an outwardly extending conical section,and the first portion or the fixation portion of the anchoring memberextends at least substantially parallel to the longitudinal dimension ofthe anchoring member.

31. A method for replacement of a native heart valve having an annulusand leaflets, the method comprising:

-   -   positioning a prosthetic heart valve device including an        anchoring member and a valve support coupled to the anchoring        member in a heart of a human, wherein the anchoring member has a        tissue fixation portion, an integration region attached to the        valve support, and a lateral portion between the tissue fixation        portion and the integration region, and wherein the tissue        fixation portion is located in an atrium of the heart;    -   expanding the anchoring member and the valve support such that a        tissue fixation portion has a size and shape configured to        contact a native mitral valve annulus;    -   moving the anchoring member and the valve support inferiorly        such that the tissue fixation portion engages target tissue at        or downstream of the native mitral valve annulus and deforms        with respect to a shape of the target tissue; and    -   wherein a support region of the valve support is mechanically        isolated from the tissue fixation portion of the anchoring        member such that the support region of the valve support has a        predetermined cross-sectional shape that supports a prosthetic        valve so that prosthetic leaflets of the prosthetic valve        contact each other sufficiently to inhibit backflow through the        prosthetic valve.

32. The method of example 31, wherein the tissue fixation portion of theanchoring member comprises a right cylinder having an outer surface thatextends at least substantially parallel to a longitudinal axis of theanchoring member such that the outer surface of the tissue fixationportion engages the native annulus tissue.

33. The method of any of examples 31-32, wherein the lateral portion hasa lateral section that extends transverse with respect to the valvesupport or the longitudinal axis of the anchoring member and at least afirst transition zone having a first bend from the lateral section tothe tissue fixation portion.

34. The method of example 32, wherein the lateral portion furtherincludes a second transition zone having a second bend from the lateralsection to the integration region.

35. The method of any of examples 33 and 34, wherein the lateral portionprojects outwardly from the integration region and the first bend isangled superiorly from the lateral portion.

36. The method of any of examples 33 and 34, wherein the lateral portionprojects outwardly from the integration region and the first bend isangled inferiorly from the lateral portion.

37. A method for replacement of a native heart valve having an annulusand leaflets coupled to the annulus, the method comprising:

-   -   positioning a prosthetic heart valve device including an        anchoring member and a valve support at a native mitral valve        location in a heart of the patient, wherein the anchoring member        has a first portion and a second portion, and the valve support        has a first region and a second region; and    -   expanding the anchoring member and the valve support while the        second portion of the anchoring member is coupled to the second        region of the valve support such that the first portion of the        anchoring member engages tissue on or downstream of the annulus        and at least partially adapts to a shape of the annulus at the        native mitral valve location;    -   wherein, upon expansion, the first region of the valve support        is spaced inwardly apart from the first portion of the anchoring        member and the first region of the valve support holds a        prosthetic valve having prosthetic leaflets such that the        prosthetic leaflets contact each other sufficiently to inhibit        backflow through the prosthetic valve after the first portion of        the anchoring member has adapted to the shape of the annulus of        the native mitral valve.

38. A prosthetic heart valve device, comprising:

-   -   a valve support having an upstream region and a downstream        region relative to blood flow through a native heart valve of a        human heart, the upstream region being configured to support a        prosthetic valve, the prosthetic valve having a plurality of        leaflets and having an undeformed shape in which the leaflets        coapt sufficiently to prevent backflow through the prosthetic        valve;    -   an anchoring member including an outwardly-facing engagement        surface configured to engage tissue at an implant site on or        below a native annulus of the native heart valve and extend in        an upstream direction at an angle generally parallel to a        longitudinal axis of the anchoring member or tapering inwardly        in the upstream direction, the fixation portion being deformable        into a non-circular shape to adapt to a shape of the tissue at        the implant site in a deployed state; and    -   a connection structure interconnecting the anchoring member to        the valve support;    -   wherein the tissue fixation portion of the anchoring member is        mechanically isolated from the upstream region of the valve        support such that the upstream region of the valve support        maintains the undeformed shape if the anchoring member has        deformed into the non-circular shape.

39. The prosthetic heart valve device of example 38 wherein theconnection structure comprises a plurality of struts each having aninner end connected to the valve support and an outer end connected tothe anchoring member.

40. The prosthetic heart valve device of any of examples 38-39 whereinthe connection structure has a flared portion that flares outwardly inthe upstream direction.

41. The prosthetic heart valve of example 40 wherein the connectionstructure is configured such that the flared portion is disposedentirely downstream of the native annulus when the anchoring member isat the implant site.

42. Prosthetic heart valve device of any of examples 38-41 wherein theconnection structure has an upstream end connected to the anchoringmember, the upstream end being configured for positioning below thenative annulus when the anchoring member is at the implant site.

43. The prosthetic heart valve device of any of examples 38-42 furthercomprising a plurality of barbs on the fixation surface, the barbspointing in the upstream direction and configured to engage the tissueto resist upstream movement of the anchoring member relative to thenative annulus.

44. The prosthetic heart valve device of any of examples 38-43 whereinthe fixation surface is deflectable through a range of angles relativeto the longitudinal axis such that upon engagement with the tissue thefixation surface is movable from an unbiased orientation to an implantedorientation.

45. The prosthetic heart valve device of example 44 wherein the fixationsurface is deflectable through a range of angles relative to theconnecting structure.

46. The prosthetic heart valve device of any of examples 38-45 whereinthe fixation portion has a first flexibility and the connectingstructure has a second flexibility different than the first flexibility.

47. The prosthetic heart valve device of any of examples 38-45 whereinthe fixation portion has a downstream region with a first flexibilityand an upstream region with a second flexibility different than thefirst flexibility.

48. The prosthetic heart valve device of any of examples 38-47 whereinthe fixation portion comprises a skirt covering an inward-facing surfacethereof.

49. The prosthetic heart valve device of example 48 wherein the skirtfurther covers an inward-facing side of the connecting structure.

50. The prosthetic heart valve device of example 48 further comprising atubular valve cover extending around the valve support, the skirt beingattached to the valve cover so as to inhibit blood flow therebetween

51. The prosthetic heart valve device of example 50 wherein the valvecover is disposed on an inward facing surface of the valve support.

52. The prosthetic heart valve device of any of examples 38-51 whereinthe fixation surface is disposed at an angle generally parallel to anoutwardly facing surface of the valve support in an unbiased condition.

53. The prosthetic heart valve device of any of examples 38-52 whereinthe valve support has a downstream end, the anchoring member beingconfigured such that the downstream end is disposed no more than 16 mmdownstream of the native annulus when the engagement surface is at theimplant site.

54. The prosthetic heart valve device of any of examples 38-53 whereinthe fixation surface has a width in a direction parallel to thelongitudinal axis of at least about 10-20 mm.

55. The prosthetic heart valve device of 38-54 wherein the connectingstructure extends a distance parallel to the longitudinal axis of lessthan about 15 mm from the inner end to the outer end.

56. A prosthetic heart valve device, comprising:

-   -   a valve support having an upstream region and a downstream        region relative to blood flow through a native heart valve of a        human heart, the upstream region being configured to support a        prosthetic valve, the prosthetic valve having a plurality of        leaflets and having an undeformed shape in which the leaflets        coapt sufficiently to prevent backflow through the prosthetic        valve; and    -   an anchoring member including a connection structure and a        fixation portion, the connection structure having an inner end        connected to the valve support, an outer end connected to the        fixation portion, and an intermediate portion between the inner        end and the outer end which flares outwardly in an upstream        direction, the fixation portion having an outwardly-facing        engagement surface configured to engage tissue at an implant        site on or below a native annulus of the native heart valve with        the flared portion of the connection structure disposed entirely        downstream of the native annulus, the engagement surface        extending in an upstream direction at an angle generally        parallel to a longitudinal axis of the anchoring member or        tapering inwardly in the upstream direction, the fixation        portion being deformable into a non-circular shape to adapt to a        shape of the tissue at the implant site in a deployed state;    -   wherein the fixation portion of the anchoring member is        mechanically isolated from the upstream region of the valve        support such that the upstream region of the valve support        maintains the undeformed shape if the anchoring member has        deformed into the non-circular shape.

57. A prosthetic heart valve device, comprising:

-   -   a valve support having an upstream region and a downstream        region relative to blood flow through a native heart valve of a        human heart, the upstream region being configured to support a        prosthetic valve, the prosthetic valve having a plurality of        leaflets and having an undeformed shape in which the leaflets        coapt sufficiently to prevent backflow through the prosthetic        valve; and    -   an anchoring member including a connection structure and a        fixation portion, the connection structure having an inner end        connected to the valve support and an outer end connected to the        fixation portion, the fixation portion having an        outwardly-facing engagement surface configured to engage tissue        at an implant site on or below a native annulus of the native        heart valve, the anchoring member having a downstream region        with a first flexibility and an upstream region with a second        flexibility different than the first flexibility, the fixation        portion being deformable into a non-circular shape to adapt to a        shape of the tissue at the implant site in a deployed state;    -   wherein the fixation portion of the anchoring member is        mechanically isolated from the upstream region of the valve        support such that the upstream region of the valve support        maintains the undeformed shape if the anchoring member has        deformed into the non-circular shape.

58. The prosthetic heart valve device of claim 57 wherein the upstreamregion is in the fixation portion and the downstream region is in theconnecting structure.

59. The prosthetic heart valve device of claim 57 wherein the upstreamregion is in an upstream portion of the fixation portion and thedownstream region is in a downstream portion of the fixation portion.

CONCLUSION

The above detailed descriptions of embodiments of the technology are notintended to be exhaustive or to limit the technology to the precise formdisclosed above. Although specific embodiments of, and examples for, thetechnology are described above for illustrative purposes, variousequivalent modifications are possible within the scope of the technologyas those skilled in the relevant art will recognize. For example, whilesteps are presented in a given order, alternative embodiments mayperform steps in a different order. The various embodiments describedherein may also be combined to provide further embodiments.

From the foregoing, it will be appreciated that specific embodiments ofthe technology have been described herein for purposes of illustration,but well-known structures and functions have not been shown or describedin detail to avoid unnecessarily obscuring the description of theembodiments of the technology. Where the context permits, singular orplural terms may also include the plural or singular term, respectively.

Moreover, unless the word “or” is expressly limited to mean only asingle item exclusive from the other items in reference to a list of twoor more items, then the use of “or” in such a list is to be interpretedas including (a) any single item in the list, (b) all of the items inthe list, or (c) any combination of the items in the list. Additionally,the term “comprising” is used throughout to mean including at least therecited feature(s) such that any greater number of the same featureand/or additional types of other features are not precluded. It willalso be appreciated that specific embodiments have been described hereinfor purposes of illustration, but that various modifications may be madewithout deviating from the technology. Further, while advantagesassociated with certain embodiments of the technology have beendescribed in the context of those embodiments, other embodiments mayalso exhibit such advantages, and not all embodiments need necessarilyexhibit such advantages to fall within the scope of the technology.Accordingly, the disclosure and associated technology can encompassother embodiments not expressly shown or described herein.

I/We claim:
 1. A prosthetic heart valve device for treating a valve of a human heart having a native annulus and native leaflets, the device comprising: an inner frame; a prosthetic valve disposed within the inner frame; and an anchoring member including a connection structure fixedly attached to the inner frame before deployment of the prosthetic heart valve device and an outer frame having interconnected struts that define an outwardly facing engagement surface configured to engage an inwardly facing surface of the native annulus, wherein, in a deployed state, the outer frame is spaced radially outward from the inner frame and the engagement surface exerts a radially outward force against an inner surface of the native annulus to affix the device to the native annulus.
 2. The device of claim 1 wherein, at an elevation corresponding to an inflow region of the inner frame, the inflow region of the inner frame is separated from an inflow region of the outer frame by a gap.
 3. The device of claim 2 wherein the inflow region of the outer frame is configured to deflect inwardly toward the inner frame when the engagement surface exerts the radially outward force against the inner surface of the native annulus.
 4. The device of claim 1 wherein, in an expanded state, a portion of the outer frame has a cylindrical shape surrounding the inner frame.
 5. The device of claim 1 wherein the outer frame has a plurality of tissue engaging elements projecting outwardly from the engagement surface in an upstream direction relative to a direction of blood flow during diastole.
 6. The device of claim 1, further comprising a fabric flexibly coupled between the inner frame and the outer frame proximate to an inlet region of the prosthetic valve.
 7. The device of claim 1, further comprising an atrial retainer coupled to the outer frame, wherein the atrial retainer extends laterally outward from an upstream end of the outer frame.
 8. A prosthetic heart valve device for treating a valve of a human heart having a native annulus and native leaflets, the device comprising: a valve support extending around a longitudinal axis, wherein the valve support has an upstream region and a downstream region, wherein the upstream region includes an upstream end of the valve support; a prosthetic valve having a plurality of leaflets carried by the valve support; and an anchoring member having an outer frame completely surrounding the upstream region of the valve support at a position along the longitudinal axis substantially the same as the upstream region of the valve support, wherein the anchoring member is resiliently biased to a deployed state in which the outer frame is spaced radially apart from the inner frame and is thereby configured to exert a radially outward force against an inner surface of the native annulus that secures the heart valve device to the native annulus.
 9. The device of claim 8 wherein the outer frame comprises a plurality of interconnected struts that extend circumferentially about the outer frame.
 10. The device of claim 9 wherein the interconnected struts have a diamond-like configuration.
 11. The device of claim 8 wherein the outer frame has an outwardly-facing engagement surface configured to press against the inner surface of the native annulus, and the outer frame is configured to be positioned between the native annulus and the valve support in the deployed state when the engagement surface presses against the inner surface of the native annulus.
 12. The device of claim 8, further comprising an atrial retainer coupled to the outer frame, and wherein the atrial retainer extends laterally outward from an upstream end of the outer frame.
 13. The device of claim 8 wherein the outer frame has an outwardly-facing engagement surface configured to press against the inner surface of the native annulus, and wherein the device further comprises a plurality of engagement elements projecting outwardly from the engagement surface.
 14. The device of claim 8, further comprising a web of flexible material extending between the valve support and the outer frame proximate to an inlet region of the prosthetic valve.
 15. A prosthetic heart valve device for treating a valve of a human heart having a native annulus and native leaflets, the device comprising: with a valve support having an upstream region and a downstream region relative to a direction of blood flow during diastole, wherein the valve support is configured to retain a prosthetic valve in at least the upstream region; and an anchoring member comprising an outer cylindrical frame having interconnected struts that define an outwardly-facing engagement surface configured to engage an inwardly-facing surface of the native annulus, wherein, in a deployed state, the outer frame is spaced radially outward from the valve support such that the engagement surface is configured to exert a radially outward force against the inwardly-facing surface of the native annulus that secures the device to the native annulus.
 16. The device of claim 15 wherein, when the device is in an unbiased expanded state, the valve support has a first diameter and the outer frame has a second diameter greater than the first diameter at an elevation corresponding to the upstream region.
 17. The device of claim 15 wherein the interconnected struts have a diamond-like configuration.
 18. The device of claim 15, further comprising an atrial retainer coupled to the anchoring member, wherein the atrial retainer extends laterally outward from an upstream portion of the outer frame and is configured to extend over a supra-annular surface of the native annulus.
 19. The device of claim 18 wherein the atrial retainer is integrally formed with the outer frame.
 20. The device of claim 18 wherein the atrial retainer comprises a plurality of ribs and a covering extending over at least a portion of the fingers. 